Various aspects of the present disclosure relate to a method and apparatus of supporting data collection. An exemplary method performed by a UE may include receiving, from a first RAN node, a data retaining indication in a handover command for a handover of the UE from a first cell of the first RAN node to a second cell of a second RAN node, wherein the data retaining indication indicates the UE to retain un-retrieved data that is measurement results associated with one or multiple cells logged in the UE but has not been reported to network; determining to retain data based on the data retaining indication; and sending, to the second RAN node, a data availability indication indicating that there is retained data to be reported in the case that there is data being retained based on the data retaining indication.
Various aspects of the present disclosure relate to method and apparatus of supporting artificial intelligence (AI) applications in wireless communications. An exemplary method performed by a UE may include: receiving, from a NE, subframe configuration and sensing reference signal configuration both associated with a sensing service request; and means for sending, to the NE, data associated with the sensing service request in radio subframes based on the subframe configuration, wherein the data is generated by an AI function and each radio subframe carrying the data also carries associated sensing reference signals configured based on the sensing reference signal configuration.
H04L 41/16 - Dispositions pour la maintenance, l’administration ou la gestion des réseaux de commutation de données, p. ex. des réseaux de commutation de paquets en utilisant l'apprentissage automatique ou l'intelligence artificielle
H04W 24/10 - Planification des comptes-rendus de mesures
Various aspects of the present disclosure relate to coordination between network nodes for DL delay measurement. In one aspect, a first network node determines change of a measured DL delay between a second network node and the first network node, or compare the measured DL delay with a first threshold. The first network node transmits, to a third network node, a first indication based on the change of the measured DL delay or comparison of the measured DL delay with the first threshold. The first indication is associated with transmission of DL sending time, measurement of a DL delay or DL scheduling based on the measurement of the DL delay.
Various aspects of the present disclosure relate to a method and apparatus of supporting internet of things (IoT). An exemplary method performed by a core network (CN) entity may include determining revocation information related to a UE in the case of determining that authorization for the UE as an AIoT reader needs to be revoked; and sending the revocation information to the UE and a RAN node associated with the UE, wherein the revocation information includes ID information of the UE and revocation indication indicating that the authorization for the UE as an AIoT reader is revoked or needs to be revoked.
The present disclosure relates to methods and apparatuses for a cell supporting a low power wake up signal (LP-WUS) or a low power synchronization signaling (LP-SS), and more specifically to methods and apparatuses for enhancements of capacity and coverage optimization (CCO) for a cell supporting LP-WUS or LP-SS. According to an embodiment of the present disclosure, a network equipment (NE) for wireless communication includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the NE to: detect an occurrence of a set of CCO issues associated with an LP-WUS or an LP-SS; and send information related to the set of CCO issues to one or more neighbour NEs.
Various aspects of the present disclosure relate to conditional SCell activation in LTM. In one aspect, a UE receives, from a first network node, a configuration for conditional SCell activation and at least one execution condition for the conditional SCell activation of an SCell during conditional LTM cell switch. The SCell is associated with an LTM candidate cell. The UE performs evaluation of the at least one execution condition for the conditional SCell activation based on the configuration for the conditional SCell activation and the at least one execution condition. In addition, the UE performs execution of the conditional SCell activation based on the configuration for the conditional SCell activation and the at least one execution condition.
Various aspects of the present disclosure relate to LTM. In one aspect, a first network node may receive, from a second network node, one or more TA values for one or more SCells associated with a candidate cell of an LTM cell switch, and transmit the one or more TA values to a UE. The UE may store the one or more TA values. As such, early TA acquisition for SCell in LTM may be achieved.
Various aspects of the present disclosure relate to data transmission in PDCP layer. In one aspect, a first device for wireless communication starts, at a PDCP entity of the first device, a first discard timer upon receiving first data from an upper layer of the first device. In turn, the first device discards the first data which is not delivered to a lower layer of the first device upon expiration of the first discard timer.
The present disclosure relates to methods and apparatuses for supporting NTN for a WAB node. A wireless network node may: receive, from a first BS or a first CN node, link type information associated with an MT part of the wireless network node, wherein the MT part of the wireless network node is connected to the first BS and the first CN node; and transmit the link type information from a BS part of the wireless network node to a second CN node, wherein the BS part of the wireless network node has an NG connection with the second CN node and serves a UE connected to the second CN node.
The present disclosure relates to methods and apparatuses for sensing performed by a UE in a connected state. The UE may: receive a sensing-related configuration from a first BS; and perform a sensing task based on the sensing-related configuration when the UE is in a connected state. Performing the sensing task may include monitoring a first sensing RS based on the sensing-related configuration and the UE may transmit a report including data corresponding to the sensing task. Performing the sensing task may include transmitting a second sensing RS based on the sensing-related configuration.
Various aspects of the present disclosure relate to PRACH transmissions. In an aspect, a user equipment determines a time period for physical random access channel (PRACH) transmissions with preamble repetitions. The user equipment transmits, to the base station, a PRACH transmission with N preamble repetitions in N valid random access channel (RACH) occasions (ROs) within the time period. The N valid ROs are associated with a beam set comprising M beams.
Various aspects of the present disclosure relate to a routing in UE-BS-UE communication. In an aspect, a user equipment assembles at least one packet data unit (PDU) with at least one routing identity (ID) for UE-base station (BS) -UE communication to at least one second UE; and transmits the at least one PDU to a first base station.
H04W 40/22 - Sélection d'itinéraire ou de voie de communication, p. ex. routage basé sur l'énergie disponible ou le chemin le plus court utilisant la retransmission sélective en vue d'atteindre une station émettrice-réceptrice de base [BTS Base Transceiver Station] ou un point d'accès
Various aspects of the present disclosure relate to uplink transmission pre-compensation. In an aspect, a user equipment (UE) determines first one or more values. The first one or more values comprises at least one of a first time advance (TA) or a first frequency domain offset. The UE performs a first transmission based on the first one or more values. The UE receives at least one signaling indicating second one or more values. The second one or more values comprise at least one of a second TA or a second frequency domain offset. The UE performs a second transmission based on the second one or more values. In this way, it is allowed to improve the communication performance.
Various aspects of the present disclosure relate to a UE, a processor for wireless communication, a network entity, and methods for performance monitoring for AI-based beam prediction at UE side. In example method, the UE receives a first CSI report configuration for a CSI report for performance monitoring, wherein the first CSI report configuration is linked with a second CSI report configuration for an AI/ML-based inference report, and wherein each resource of a first resource set associated with the first CSI report configuration for monitoring measurement is mapped to one or more resources of a second resource set associated with the second CSI report configuration for beam prediction. The UE further determines based on the first CSI report configuration, a number N of CSI-RS or SSB transmission occasions for monitoring result calculation, wherein N is configured in the first CSI report configuration.
Various aspects of the present application relate to methods and apparatuses for supporting an inter-secondary node (SN) secondary cell group (SCG) layer-1/layer-2 (L1/L2) -triggered mobility (LTM). According to an embodiment of the present application, a master node (MN) for wireless communication includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the MN to: obtain one or more security identities (IDs) for one or more LTM candidate primary secondary cell group cells (PSCells) prepared at one or more candidate SNs; and send, to the one or more candidate SNs, the one or more security IDs and security information associated with each security identity (ID) within the one or more security IDs, wherein the security information is used for security key updating during an LTM performed by a user equipment (UE) from an LTM serving PSCell in a source SN towards one LTM candidate PSCell within the one or more LTM candidate PSCells.
Various aspects of the present disclosure relate to CSI reporting for SSB. In an aspect, a UE receives, from a network entity, a channel state information (CSI) report configuration associated with at least one synchronization signal and physical broadcast channel block (SSB). The at least one SSB comprises at least one first SSB. The UE transmits, to the network entity, a CSI report associated with one or more SSBs among the at least one SSB. The one or more SSBs comprises one or more first SSBs among the at least one first SSB.
Various aspects of the present disclosure relate to methods and apparatuses for channel state information – reference signal (CSI-RS) transmission. Some implementations of the methods and apparatuses described herein may include a user equipment (UE) for wireless communication, comprising: at least one memory; and at least one processor coupled with the at least one memory and configured to cause the UE to: receive a configuration indicating a frequency density of a first CSI-RS resource which includes a number of second CSI-RS resources, and physical resource block (PRB) locations associated with the number of second CSI-RS resources, wherein the frequency density is smaller than 1/2 resource element (RE) per PRB per port; receive a CSI-RS on the first CSI-RS resource based on the configuration; and transmit a channel state information (CSI) report based on the CSI-RS.
Various aspects of the present disclosure relate to a paging alert signal. In a solution of the disclosure, a terminal device determines one or more time instances based on at least one of a configuration for reporting channel state information (CSI) or a time instance of transmitting CSI. Then, the terminal device transmits, to a network device, one or more CSI associated with the one or more time instances. The one or more CSIs are for performance monitoring or model inference.
Various aspects of the present disclosure relate to segmentation at a PDCP entity for data transmission. In one aspect, a first device for wireless communication performs, at a PDCP entity of the first device, segmentation of a PDCP SDU or a portion comprising the PDCP SDU and a MAC-I associated with the PDCP SDU to generate a segment. In turn, the first device transmits a PDU including the segment to a second device for wireless communication. The PDCP PDU comprises information related to the segmentation. With this solution, segmentation of a PDCP SDU can be performed at a PDCP entity instead of RLC entity, and thus implementation of the first device may be simplified.
Various aspects of the present disclosure relate to a UE, a network entity, a processor for wireless communication, methods, and a computer readable medium for supporting multiple TAs in multiple TRPs. The UE receives information indicating more than one TAGs for a serving cell, wherein the UE is provided with multiple joint or DL indicated beams for the serving cell. The UE further receives a PDCCH order via more than one beams. The UE further transmits a PRACH triggered by the PDCCH order based on a PL-RS, wherein the PL-RS is determined according to one of the more than one beams of the PDCCH order, or a SSB indicated by the PDCCH order, or a beam indicated by the PDCCH order from the multiple joint or DL indicated beams.
H04W 72/232 - Canaux de commande ou signalisation pour la gestion des ressources dans le sens descendant de la liaison sans fil, c.-à-d. en direction du terminal les données de commande provenant de la couche physique, p. ex. signalisation DCI
Various aspects of the present disclosure relate to detection of a sensing non-allowed area. In an aspect, a sensing function (SF) receives information associated with a sensing task from a sensing entity. The SF determines to stop or revoke the sensing task based on the received information and transmits, to an application function (AF), an identity (ID) of the sensing task and an indication of stopping or revoking the sensing task.
Various aspects of the present disclosure relate to configuration of model/functionality for CSI reporting. In an aspect, a UE receives, from a network entity, configuration information for a model or a functionality. The configuration information is associated with channel state information (CSI) reporting that is based on at least one or more historical CSIs. The UE determines the model or functionality based on the configuration information.
Various aspects of the present disclosure relate to TCI state activation of SCell in LTM. In one aspect, a first network node receives at least one TCI state configuration. Each of the at least one TCI state configuration is for a respective one of at least one SCell. The at least one SCell is associated with an LTM candidate cell. The first network node transmits, based on the at least one TCI state configuration to a UE, information related to activation or deactivation of at least one TCI state of the at least one SCell.
Various aspects of the present disclosure relate to channel state information (CSI) reporting. In one solution, a terminal device receives, from a network device, an indication to reset or retransmit CSI. The terminal device then transmits a CSI report to the network device in response to the indication.
H04L 5/00 - Dispositions destinées à permettre l'usage multiple de la voie de transmission
H04W 72/21 - Canaux de commande ou signalisation pour la gestion des ressources dans le sens ascendant de la liaison sans fil, c.-à-d. en direction du réseau
An electronic device includes: a first body; a connection assembly, including a panel group; a second body, connected to the first body via the connection assembly; and a deformable screen, including a first part connected to the first body, a second part connected to the second body, and a deformable part positioned between the first part and the second part, where if the first body and the second body switch from a first device posture to a second device posture via the connection assembly, the panel group of the connection assembly form an accommodation space to receive and protect at least a portion of the deformable part of the deformable screen.
The present disclosure relates to methods and apparatuses for integrated sensing and communication in a mobility scenario. A first BS may: transmit, to a second BS or a CN node, a first message requesting cell switching of a first UE to the second BS, wherein the first message comprises an ID of the first UE and a sensing indication; receive, from the second BS or the CN node, a configuration for the cell switching; and transmit, to the first UE, the configuration for the cell switching.
Various aspects of the present disclosure relate to a method and apparatus of supporting internet of things (IoT). An exemplary method performed by a CN entity for wireless communication may include receiving, from an AIoT reader, a request message associated with an AIoT device at least to access the core network, wherein the request message is based on a D2R transmission generated internally by the AIoT device; performing access control for the AIoT device; and determining an AF to which traffics from the AIoT device will be routed in the case that the request message is accepted based on the access control by the CN entity.
The embodiments of the present application provide an interaction processing method and apparatus. The interaction processing method comprises: in response to a target trigger event, displaying a target virtual image set (S101), the target virtual image set being generated on the basis of a target device group created by a target user, and the target device group comprising at least one electronic device; in response to an interactive operation acting on a target virtual image set, updating a virtual image parameter and/or an operating configuration parameter of a target device in the target device group (S102), wherein the target device group comprises an electronic device occupied or not occupied by the target user, and the target device is the electronic device occupied or not occupied by the target user.
G06F 3/0484 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI] pour la commande de fonctions ou d’opérations spécifiques, p. ex. sélection ou transformation d’un objet, d’une image ou d’un élément de texte affiché, détermination d’une valeur de paramètre ou sélection d’une plage de valeurs
Various aspects of the present disclosure relate to UPF-based local caching. In an aspect, a SMF receives first information associated with a protocol data unit (PDU) session of a user equipment (UE) or an application server. The SMF determines to trigger an operation of user plane function (UPF) -based local caching for traffic transmitted via the PDU session or traffic associated with the application server.
Various aspects of the present application relate to methods and apparatuses for supporting a layer-1/layer-2 (L1/L2) -triggered mobility (LTM). According to an embodiment of the present application, a network equipment (NE) includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the NE to: determine a report configuration for reporting channel state information (CSI) of one or more channel state information-reference signal (CSI-RS) resources of an LTM candidate cell of a user equipment (UE); and send the report configuration to the UE.
Embodiments of the present disclosure relate to method and apparatus for HARQ-ACK feedback timing determination in low band CA. According to some embodiments of the disclosure, a UE may: receive, from a BS, signaling indicating a carrier switching pattern; receive, from the BS, a first PDSCH on the second carrier in a first downlink slot; determine a first uplink slot on the first carrier for the UE to transmit HARQ-ACK feedback for the first PDSCH based on a HARQ-ACK feedback timing reference, a set of PDSCH-to-HARQ feedback timing values dedicated for the second carrier, or a PDSCH-to-HARQ feedback timing indicator associated with the second carrier and indicating the first uplink slot on the first carrier; and transmit, to the BS, the HARQ-ACK feedback in the first uplink slot on the first carrier.
Various aspects of the present disclosure relate to support contention resolution of contention based random access, such as contention resolution of contention based random access for an AIoT device. In an aspect, a first device transmits, to a second device, a first message after the first device determines to initiate a contention based random access procedure. The first message comprises a first random identity (ID). The first device determines whether at least one second random ID in at least one second message matches the first random ID. The at least one second message is part of a set of second messages from the second device after transmission of the first message.
Various aspects of the present disclosure relate to methods and apparatuses for extremely large-scale multiple-input multiple-output (MIMO) transmission with subarrays. Some implementations of the methods and apparatuses described herein may include a user equipment (UE) for wireless communication, which may include: at least one memory; and at least one processor coupled with the at least one memory and configured to cause the UE to:receive a downlink (DL) reference signal (RS) from an antenna array of a network equipment (NE); determine, based on the DL RS, a minimum number of subarrays that the antenna array can be partitioned into for transmission to the UE; and transmit a channel state information (CSI) feedback indicating the minimum number of subarrays.
Various aspects of the present disclosure relate to a random access procedure. In an aspect, a user equipment (UE) receives a first configuration of random access channel (RACH) resources for first message repetitions with different beams. The first message repetitions with different beams correspond to a feature or a feature combination, and the first configuration is separately from a second configuration of RACH resources for first message repetitions with the same beam, or is within the second configuration. The UE transmits the first message repetitions with different beams in the RACH resources. The UE receives a second message comprising an indication associated with a beam identity (ID). Based on the indication, the UE determines the beam ID. Then the UE transmits a third message using a beam associated with the beam ID.
The present disclosure relates to methods and apparatuses for L1 measurement report and conditional LTM. AUE may: transmit, to a BS, a first message, wherein the first message is associated with at least one of MR or CLTM; receive, from the BS, an RRC reconfiguration message, wherein the RRC reconfiguration message includes one or more of an L1 event configuration, L1 measurement report configuration, a CLTM candidate configuration and a CLTM execution condition configuration; and determine to perform a handover related operation based on the received RRC reconfiguration message.
Various aspects of the present disclosure relate to a reader-to-device (R2D) transmission in an ambient Internet of things (A-IoT) system. In an aspect, a first device (for example, a reader) determines information associated with a transport block size (TBS) field. The TBS field is used to indicate a payload size for a physical reader-to-device channel (PRDCH) in an R2D transmission to a second device (for example, an A-IoT device). Moreover, the first device performs the R2D transmission that indicates the information associated with the TBS field. In addition, the second device determines an end of the PRDCH based on the information associated with the TBS field indicated in the received R2D transmission. In this way, it is allowed to improve communication performance in the A-IoT system.
H04L 1/00 - Dispositions pour détecter ou empêcher les erreurs dans l'information reçue
H04W 4/80 - Services utilisant la communication de courte portée, p. ex. la communication en champ proche, l'identification par radiofréquence ou la communication à faible consommation d’énergie
Various aspects of the present disclosure relate to a sensing fusion. In one aspect of the solution of the present disclosure, a sensing function (SF) transmits first sensing task information to a first device. The first sensing task information comprises an identity (ID) of a sensing task, and at least one of an indication of sensing fusion or an ID of a second device.
Various aspects of the present disclosure relate to RAT-dependent positioning in NTN. In one aspect, a UE may receive ephemeris information of a TRP for positioning, and perform a RAT-dependent positioning procedure based on the ephemeris information. In this way, RAT-dependent positioning in NTN may be carried out.
Various aspects of the present disclosure relate to a UE, a processor for wireless communication, a network entity, and methods for supporting UE-sided artificial intelligence AI-based CSI prediction. In the method, the UE transmits a signalling indicating at least one supported or applicable parameter set for AI/ML-based CSI prediction; and performs data collection for model training or model inference based on a CSI report configuration associated with one of the at least one supported or applicable parameter set for CSI prediction.
Various aspects of the present disclosure relate to sensing signal communication. In an aspect, a user equipment (UE) receives, from a base station (BS), configuration information for sensing signal transmission, wherein the configuration information comprises transmission information associated with different types of sensing signal transmission. Further, the UE receives, from the BS, indication information that indicates a type of sensing signal transmission. Moreover, the UE performs the type of sensing signal transmission as indicated by the BS, to a sensing BS or a sensing UE. In this way, it is allowed to achieve efficient sensing of the environment or object.
Various aspects of the present disclosure relate to support mapping between devices, such as mapping between devices related to an AIoT device and a UE. In an aspect, a first apparatus transmits, to a second apparatus, a request for mapping relationship between at least one device identity (ID) and at least one user equipment (UE) ID. The first apparatus receives, from the second apparatus, the mapping relationship.
Various aspects of the present disclosure relate to activation or deactivation of SCell in LTM. In one aspect, a first base station receives, from a UE, capability information related to activation or deactivation of an SCell. The first base station transmits, to the UE, a configuration of an LTM candidate cell prepared by a second base station. In turn, the first base station transmits, to the UE, a first indication indicating activation or deactivation of one or more first SCells associated with the first LTM candidate cell.
Various aspects of the present disclosure relate to a paging alert signal. In a solution of the disclosure, a terminal device receives, from a network device, downlink control information (DCI) related to updating an indicated beam of one or more indicated beams in a serving cell. Then, the terminal device transmits, to the network device, a channel state information (CSI) report based on the DCI, wherein the CSI report is determined based on a report configuration and is associated with the indicated beam.
Various aspects of the present disclosure relate to registration and authentication using multiple certificates. A network equipment (NE) may transmit a request for a vendor-signed certificate to a server device associated with a vendor of the NE and based on a security key and a fully qualified domain name (FQDN). The NE may receive the vendor-signed certificate from the server device associated with the vendor of the NE. The NE may transmit a request for an operator-signed certificate to a server device associated with an operator of the NE and based on the vendor-signed certificate. The NE may receive the operator-signed certificate from the server device associated with the operator of the NE. The NE may establish a secure connection between the NE and a core network (CN) based on the vendor-signed certificate and the operator-signed certificate.
Various aspects of the present disclosure relate to scheduling of DL PDU set based on DL delay. In one aspect, a first network node receives, from a second network node, DL sending time of a start PDU in a PDU set sent by the second network node to the first network node. In turn, the first network node schedules transmission of the PDU based on the DL sending time of the start PDU.
Various aspects of the present disclosure relate to a method and apparatus of supporting timely retransmissions. An exemplary method performed by a CU of a RAN node may include: determining retransmission related information for timely retransmissions of a DRB between the RAN node and a UE, including one or multiple of: downlink retransmission related information or uplink retransmission related information, wherein the timely retransmissions include one or multiple of RLC autonomous retransmission or remaining time based RLC polling in RLC AM; and transmitting the retransmission related information to a DU of the RAN node associated with the UE.
Embodiments of the present disclosure relate to method and apparatus for Type-1 HARQ-ACK codebook generation in low band CA. According to some embodiments of the disclosure, a UE may: receive, from a BS, signaling indicating a carrier switching pattern, wherein the carrier switching pattern indicates a first number of slots for the UE to receive downlink transmission on a first carrier and a second number of slots for the UE to receive downlink transmission on a second carrier; receive, from the BS, a PDSCH on the first carrier or the second carrier; determine a set of valid candidate PDSCH reception occasions on the first carrier and the second carrier, wherein the PDSCH is received within the set of valid candidate PDSCH reception occasions; generate HARQ-ACK feedback corresponding to the set of valid candidate PDSCH reception occasions and the PDSCH; and transmit, to the BS, the generated HARQ-ACK feedback on the first carrier.
Various aspects of the present disclosure relate to a method and apparatus of supporting artificial intelligence (AI) applications in wireless communications. An exemplary method performed by a UE may include receiving, from a first network equipment (NE), a handover related configuration to execute a handover from the first NE to a second NE; and sending applicability related information to the second NE during the handover, wherein the applicability related information includes one or multiple of configuration applicability related information for each prediction configuration maintained at the UE or parameter applicability related information for each prediction configuration related parameter or parameter set maintained at the UE.
Various aspects of the present disclosure relate to configurations for LP-WUS related procedures. In an aspect, a UE receives, from a network entity, a configuration comprising at least one condition for at least one low-power wakeup signal (LP-WUS) related procedure. The UE determines whether to perform the at least one LP-WUS related procedure based on the at least one condition.
The present disclosure relates to wireless communications, and more specifically to methods and apparatuses of a minimization of drive tests (MDT) mechanism for a user equipment (UE) supporting low power wake up radio (LP-WUR) or low power wake-up receiver (LR). According to an embodiment of the present disclosure, a network equipment (NE) for wireless communication includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the NE to: obtain an MDT configuration used for a user equipment (UE) to log or report MDT measurement information, wherein the MDT configuration includes at least one of the following: a main receiver (MR) specific MDT configuration; a low power wake-up receiver (LR) specific MDT configuration; or a common MDT configuration;and transmit the MDT configuration to the UE.
The present disclosure relates to methods and apparatuses for SCell activation in the LTM procedure. A UE may: transmit a capability related message to a BS, wherein the capability related message is associated with at least one of a CG resource of an SCell for cell switching, or candidate SCell activation via a MAC CE; receive an RRC reconfiguration message from the BS, wherein the RRC reconfiguration is based on the capability related message and includes at least one of an L1 measurement configuration or an LTM candidate configuration; and receive a first MAC CE from the BS, wherein the first MAC CE indicates activation of at least one SCell, and the at least one SCell is associated with the LTM candidate configuration.
Various aspects of the present disclosure relate to a UE, a network entity, a processor for wireless communication, methods, and a computer readable medium for beam determination for multiple TRPs The UE receives configuration information indicating that each CORESET is configured with one of N CORESET pools, wherein each of the N CORESET pools is associated with more than one joint, DL or UL indicated beams of M joint, DL or UL indicated beams, where M and N are positive integers and M is greater than N. The UE determines at least one beam of a PDSCH scheduled or activated by a fallback DL DCI format based on the more than one joint or DL indicated beams associated with a CORESET pool where a CORESET in which a first PDCCH carrying the fallback DL DCI format is transmitted is associated.
H04W 72/232 - Canaux de commande ou signalisation pour la gestion des ressources dans le sens descendant de la liaison sans fil, c.-à-d. en direction du terminal les données de commande provenant de la couche physique, p. ex. signalisation DCI
53.
METHOD AND APPARATUS OF SUPPORTING WIRELESS COMMUNICATIONS BASED ON SPLIT RADIO ACCESS NETWORK (RAN) ARCHITECTURE
Various aspects of the present disclosure relate to a method and apparatus of supporting wireless communications based on a split radio access network (RAN) architecture. An exemplary method performed by a DU of a NE may include: receiving, from a CU of the NE, RRC security related information, wherein the RRC security related information at least indicates key information related to RRC security keys for protection of RRC signaling between the DU and a UE; and performing security processing on the RRC signaling between the DU and UE based on the RRC security related information.
Various aspects of the present disclosure relate to a paging alert signal. In a solution of the disclosure, obtains, from a network device, information related to a time instance for monitoring an alert signal. The terminal device receives the alert signal based on the information. The alert signal comprises a sequence or a physical downlink control channel (PDCCH). Then, the terminal device determines alert information based on the alert signal. The alert information comprises at least one of: a priority or emergency level of the alert information, a type of information related to the alert signal, or one or more terminal devices to which the alert signal is targeted.
Various aspects of the present disclosure relate to decentralized device authentication using certificates. A first device implementing a first network function (NF) receives a first authentication request from a second device implementing a second NF. The first authentication request corresponds to inter-domain authentication between the second device and a third device implementing a third NF and includes a certificate of the second device. The first device transmits a second authentication request to a fourth device implementing a fourth NF and based on an intra-domain authentication between the first device and the second device being successful. The second authentication request corresponds to the inter-domain authentication between the second device and the third device and includes a certificate of the first device. The first device establishes a secure connection between the second device and the third device based on successful inter-domain authentication between the second device and the third device.
Various aspects of the present disclosure relate to constrain of energy consumption. In one aspect, a UE receives information related to energy consumption from a first network entity. In turn, the UE handles data transmission based on the information related to energy consumption.
Various aspects of the present disclosure relate to on-demand common channels and signals. In an aspect, a UE detects a signal and determines that a type of a synchronization signal block (SSB) of a cell is a first SSB type based on the detected signal. The UE detects, from a network entity, the SSB in a synchronization raster using a transmission pattern for the first SSB type. The UE transmits, to the network entity, a wakeup signal to trigger activation of a configuration for at least one common channel or signal. The at least one common channel or signal is associated with the SSB or a first set of SSBs of the first SSB type comprising the SSB.
Various aspects of the present disclosure relate to a UE, a processor for wireless communication, a network entity, and methods for channel state information (CSI) reporting for monitoring UE sided CSI prediction. In example method, the UE receives a first CSI report configuration for monitoring CSI prediction, wherein the first CSI report configuration is linked to a second CSI report configuration for time domain CSI prediction reporting associated with one or more prediction time instances. The UE further transmits a first CSI report for monitoring CSI prediction on a physical uplink shared channel (PUSCH), based on the first CSI report configuration.
Various aspects of the present disclosure relate to methods and apparatuses for channel state information (CSI) reporting. Some implementations of the methods and apparatuses described herein may include a user equipment (UE) for wireless communication, including: at least one memory; and at least one processor coupled with the at least one memory and configured to cause the UE to: receive a configuration for CSI reporting indicating one or more sets of channel measurement resources, wherein each set of channel measurement resources includes one or more subsets of channel measurement resources; determine one or more subsets of aggregated CSI ports based on the configuration, wherein each subset of aggregated CSI ports consists of CSI ports associated with channel measurement resources in one subset of channel measurement resources; and transmit a CSI report based on the one or more subsets of aggregated CSI ports.
Various aspects of the present disclosure relate to AS ID allocation for an A-IoT device. In one aspect, a first device receives a message from a second device. The message may comprise an AS ID and first information indicating the AS ID is allocated to the first device. In turn, the first device communicates with the second device based on the AS ID.
Various aspects of the present disclosure relate to a device-to-reader (D2R) transmission based on a synchronization signal in an ambient Internet of things (A-IoT) system. In an aspect, a device (for example, an A-IoT device) receives a first transmission related to A-IoT communication. The first transmission comprises a synchronization signal. Moreover, the device performs a second transmission on a time domain resource of one or more time domain resources indicated in the first transmission. The one or more time domain resources are determined based on a reference time in the first transmission preceding the synchronization signal. In this way, it is allowed to improve communication performance in the A-IoT system.
H04W 72/25 - Canaux de commande ou signalisation pour la gestion des ressources entre terminaux au moyen d’une liaison sans fil, p. ex. liaison secondaire
Various aspects of the present disclosure relate to mechanism for data processing and transmission. In an aspect, a UE receives, from a second apparatus, a transport block. The transport block comprises at least one data stream and at least one non-data stream at a physical (PHY) layer, and each of the at least one data stream and the at least one non-data stream at the PHY layer comprises at least one code block (CB). Alternatively, at least one check code is associated with at least one non-data stream of the transport block at a medium access control (MAC) layer.
Various aspects of the present disclosure relate to cell reselection. In one aspect, a UE obtains, from a first cell, at least one of the following: at least one of cell reselection parameters or cell selection parameters related to LP-SS; or at least one of cell reselection parameters or cell selection parameters related to SSB. The UE evaluates whether to fulfil cell reselection criteria for a second cell based on at least one of the following: the at least one of cell reselection parameters or cell selection parameters related to LP-SS; or the at least one of cell reselection parameters or cell selection parameters related to SSB. The second cell is a neighbour cell of the first cell.
Various aspects of the present disclosure relate to ambient Internet of things (A-IoT) positioning. In an aspect, an A-IoT device receives, from an A-IoT reader, a reader-to-device (R2D) transmission. The R2D transmission comprises a transmission parameter that indicates a granularity for time measurements. Further, the A-IoT device determines a clock speed corresponding with the transmission parameter. Moreover, the A-IoT device performs time measurements using the clock speed for a positioning determination procedure of the A-IoT device. In this way, it is allowed to support efficient A-IoT positioning, and thus improve communication performance in the A-IoT system.
The present application discloses a resource management method and apparatus and a device. The method comprises: in response to a first request, using a first service to generate a second request for a first application, the first request representing an image encoding or decoding request, the first service representing an image encoding and decoding service, and the second request representing a hardware storage resource allocation request; on the basis of the first application, using the first service to generate corresponding identification information for the second request, the identification information being used for indicating whether hardware storage resources allocated to the second request are allowed to be passively recycled; and on the basis of the second request, using a second service to allocate the hardware storage resources to the second request, the second service representing a hardware storage resource management service, and the hardware storage resources representing storage resources used for performing image encoding or decoding.
H04N 19/37 - Procédés ou dispositions pour le codage, le décodage, la compression ou la décompression de signaux vidéo numériques utilisant des techniques hiérarchiques, p. ex. l'échelonnage avec dispositions pour attribuer des priorités de transmission différentes aux données vidéo d’entrée ou aux données vidéo codées
H04N 19/423 - Procédés ou dispositions pour le codage, le décodage, la compression ou la décompression de signaux vidéo numériques caractérisés par les détails de mise en œuvre ou le matériel spécialement adapté à la compression ou à la décompression vidéo, p. ex. la mise en œuvre de logiciels spécialisés caractérisés par les dispositions des mémoires
H04N 19/156 - Disponibilité de ressources en matériel ou en calcul, p. ex. codage basé sur des critères d’économie d’énergie
A display control method includes: in response to obtaining a target interaction operation, controlling a target device to enter a target display mode corresponding to the target interaction operation; and determining a target display area based on the target display mode to output target content in the target display area, wherein the target interaction operation includes an operation acting on a target interaction area of an electronic device and/or an operation triggering a state change of a communication port of the electronic device, and the target device includes or does not include the electronic device.
G06F 3/04883 - Techniques d’interaction fondées sur les interfaces utilisateur graphiques [GUI] utilisant des caractéristiques spécifiques fournies par le périphérique d’entrée, p. ex. des fonctions commandées par la rotation d’une souris à deux capteurs, ou par la nature du périphérique d’entrée, p. ex. des gestes en fonction de la pression exercée enregistrée par une tablette numérique utilisant un écran tactile ou une tablette numérique, p. ex. entrée de commandes par des tracés gestuels pour l’entrée de données par calligraphie, p. ex. sous forme de gestes ou de texte
G06F 3/14 - Sortie numérique vers un dispositif de visualisation
67.
MODEL TRAINING AND MONITORING FOR CHANNEL STATE INFORMATION TRANSMISSION
Various aspects of the present disclosure relate to model training and monitoring for CSI transmission. In an aspect, a UE receives, from a network entity, information comprising at least one of one or more channel state information (CSI) feedbacks or one or more recovered CSIs or a downlink reference signal (DL RS). The UE determines one or more first CSIs paired with the information.
Various aspects of the present disclosure relate to a UE, a processor for wireless communication, a network entity, and methods for supporting data transmission with more than 8 layers. In the method, the UE receives, from a network entity, a scheduling signaling to schedule a physical downlink shared channel (PDSCH) including one or more codewords with more than 8 layers, and further determines layer mapping of the one or more codewords to the layers.
Various aspects of the present disclosure relate to code division multiple access (CDMA) -based communication in an ambient Internet of things (A-IoT) system. In an aspect, a first device (for example, an A-IoT device) receives a first transmission from a second device (for example, a reader). The first transmission comprises an indication indicating code division multiple access (CDMA) is enabled for communication between the first device and the second device. Moreover, the first device performs a second transmission to the second device based on the indication. In this way, it is allowed to improve communication performance in the A-IoT system.
Various aspects of the present disclosure relate to resource allocation. In an aspect, a UE determines repetition parameters for a transmission, wherein the transmission is a physical uplink shared channel (PUSCH) transmission scheduled by downlink control information (DCI) format 0_0 with cyclic redundancy check (CRC) scrambled by cell radio network temporary identifier (C-RNTI). The UE transmits, to a network entity, the transmission with repetition based on the repetition parameters. The repetition parameters comprise at least one of the following: a repetition number, a repetition type, an available slot counting manner, a frequency domain hopping type, a frequency domain hopping offset, a time domain window length for joint channel estimation, a repetition symbol type, or a starting resource block (RB) offset.
H04W 72/232 - Canaux de commande ou signalisation pour la gestion des ressources dans le sens descendant de la liaison sans fil, c.-à-d. en direction du terminal les données de commande provenant de la couche physique, p. ex. signalisation DCI
71.
RESOURCE ALLOCATION OF CDMA-BASED COMMUNICATION IN A-IOT SYSTEM
Various aspects of the present disclosure relate to resource allocation of code division multiple access (CDMA) -based communication in an ambient Internet of things (A-IoT) system. In an aspect, a first device (for example, an A-IoT device) receives, from a second device (for example, a reader), a reader-to-device (R2D) transmission. The R2D transmission indicates code-domain resource information for a CDMA-based device-to-reader (D2R) transmission from the first device to the second device. Moreover, the first device performs the CDMA-based D2R transmission based on the code-domain resource information. In this way, it is allowed to improve communication performance in the A-IoT system.
Various aspects of the present application relate to methods and apparatuses of an enhancement for a conditional layer-1/layer-2 (L1/L2) -Triggered Mobility (LTM) for master cell group (MCG). According to an embodiment of the present application, a user equipment (UE) includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the UE to: transmit capability information of the UE to a source network equipment (NE), wherein the capability information is associated with at least one of the following: multiple transmission reception points (mTRP) configured for an LTM candidate cell, or two timing advance groups (TAG) sconfigured for the LTM candidate cell; receive an LTM candidate configuration associated with one or more LTM candidate cells of the source NE and a set of execution conditions corresponding to the one or more LTM candidate cells; and trigger to perform a cell switch towards one LTM candidate cell in response to fulfillment of one or more execution conditions within the set of execution conditions corresponding to the one LTM candidate cell or in response to reception of an LTM cell switch command associated with the one LTM candidate cell.
Various aspects of the present disclosure relate to mobility robustness optimisation (MRO) for failure in L1 (layer 1) /L2 (layer 2) triggered mobility (LTM), such as identification of mobility failure in LTM. In an aspect, a first device receives first information for at least one of: determining a type of failure in L1 (layer 1) /L2 (layer 2) triggered mobility (LTM) or indicating the type of the failure, wherein the failure is associated with at least one of a beam or a timing advance (TA). The first device transmits second information comprising at least one of information for indicating the type of the failure or information for determining the type of the failure.
Various aspects of the present disclosure relate to configuration and transmission in full duplex scenarios. In an aspect, a UE receives, from a network entity, a first indication of configurations for control resource set. The UE determines at least one of a first control resource set in a time unit configured with an uplink subband or a second control resource set in a time unit with no uplink subband based on the first indication. There is no overlapping between the first control resource set and an uplink subband in frequency domain in the time unit configured with the uplink subband.
Various aspects of the present disclosure relate to determining A-IoT device position. In a solution of the disclosure, an A-IoT reader transmits a carrier wave transmission to an A-IoT device. The A-IoT device receives, from the A-IoT device, a device to reader (D2R) transmission backscattered based on the carrier wave transmission. The D2R transmission comprises at least one wave characteristic difference compared with the carrier wave transmission. Then, the A-IoT device calculates, based on the at least one wave characteristic difference of the D2R transmission, time of flight (ToF) of the carrier wave transmission to the A-IoT device and the D2R transmission from the A-IoT device, for determining positioning information of the A-IoT device.
Various aspects of the present disclosure relate to a superimposed pilot and data transmission. In a solution of the disclosure, a terminal device receives, from a network device, a configuration for a transmission of a data channel and a reference signal on a set of resources. Then, the terminal device performs one of the following: receiving the data channel and the reference signal based on the configuration, or transmitting the data channel and the reference signal based on the configuration.
Various aspects of the present disclosure relate to group-based transmission in sensing. In an aspect, a first UE receives, from a network entity, a configuration associated with a group at least comprising a first UE and a second UE. The first UE obtains at least a portion of sensing measurements of the second UE, and transmits, to a first apparatus, the at least a portion of the sensing measurements based on the configuration.
The present disclosure relates to methods and apparatuses for inter-BS LTM, L1 measurement report and CSI acquisition. A UE may: transmit, to a first BS, UE capability information related to UE-based TA measurement for inter-BS LTM or SP CSI-RS resource associated with a candidate cell; and receive, from the first BS, an RRC reconfiguration message including at least one of an LTM candidate configuration, an SP CRS-RS resource configuration, or an ID of UE-based TA measurement for each candidate cell.
Various aspects of the present disclosure relate to downlink control information (DCI) design. In an aspect, a user equipment (UE) receives a DCI scheduling an uplink transmission. The DCI comprises at least one of the following to indicate information on an orthogonal cover code (OCC) associated with the uplink transmission: a modulation and coding scheme (MCS) field, a repetition number field, a redundancy version (RV) field, a subcarrier indication field, a resource reservation field, a separate field for indicating the OCC, or a joint field for indicating at least two functionalities. The information on the OCC indicates at least one of whether the OCC is activated or deactivated for the uplink transmission, and a sequence index of the OCC. Moreover, if the UE determines that the OCC is activated for the uplink transmission, it performs the uplink transmission based on the OCC with the sequence index; or if the UE determines that the OCC is deactivated for the uplink transmission, it performs the uplink transmission without the OCC. In this way, it is allowed to improve the communication performance.
Various aspects of the present disclosure relate to MCS determination for PUSCH transmission. In an aspect, a UE determines a first modulation and coding scheme (MCS) index table based on a physical uplink shared channel (PUSCH) type of a PUSCH transmission. A number of entries supporting π/2 binary phase shift keying (BPSK) modulation in the first MCS index table is larger than a number of entries supporting π/2 BPSK modulation in a second MCS index table. The first MCS index table and the second MCS index table are applied for a same PUSCH type. The UE transmits, to a network entity, the PUSCH transmission using a modulation order and a target code rate. The modulation order and the target code rate are determined based on the first MCS index table and an indication indicative of an MCS index for the PUSCH transmission.
Example embodiments of the present disclosure relate to a UE, a BS, methods, apparatuses, processors, and computer readable medium for controlling of reference signal measurement. A UE may receive a first measurement configuration for LP-RS from a BS, where the first measurement configuration may include a first measurement object configuration associated with the LP-RS and a first measurement report configuration associated with the LP-RS. The UE may perform a measurement based on the first measurement configuration and transmit a report based on the first measurement report configuration. In the solution, the BS may transmit LP-RS without transmitting MR-RS, and the UE may detect LP-RS on LR, as such, the power saving can be achieved.
Various aspects of the present disclosure relate to UL synchronization occasion prediction. In one aspect, a UE receives a first configuration for UL synchronization occasion prediction from a base station. Then, the UE performs the UL synchronization occasion prediction to generate predicted UL synchronization occasion information based at least on the first configuration. Further, the UE transmits the predicted UL synchronization occasion information to the base station
Various aspects of the present disclosure relate to frequency correction in a non-terrestrial network (NTN). In an aspect, a user equipment (UE) receives a command for frequency correction in an NTN. The command indicates an offset value. Further, the UE determines a frequency offset for a signal based on the offset value. Moreover, the UE transmits the signal based on the frequency offset. In this way, it is allowed to improve the communication performance in the NTN.
Various aspects of the present disclosure relate to a method and apparatus of configuring user equipment (UE). An exemplary UE may include at least one memory; and at least one processor coupled with the at least one memory and configured to cause the UE to: receive, from a first network equipment (NE), a first configuration, wherein the first configuration is a basic configuration for radio protocol layer operations by the UE in radio resource control (RRC) connected state and can be maintained when the UE is in RRC inactive or RRC idle state; receive, from the first NE or a second NE, information indicating whether to keep or release the first configuration; and keep or release the first configuration based on the information indicating whether to keep or release the first configuration.
Various aspects of the present disclosure relate to positioning for an ambient Internet of things (A-IoT) device. In an aspect, a reader node detects a first path of a carrier wave transmission from a carrier wave source. A time of detecting the first path of the carrier wave transmission is determined as a reference time of the carrier wave transmission. Further, the reader node detects a second path of the carrier wave transmission that is backscattered from an A-IoT device. A time of detecting the second path of the carrier wave transmission is determined as an arrival time of the carrier wave transmission. Moreover, the reader node determines a relative time of arrival of the carrier wave transmission for use in determining a location of the A-IoT device. The relative time of arrival is based on the reference time and the arrival time of the carrier wave transmission. In this way, it is allowed to support efficient positioning in the A-IoT system.
Various aspects of the present disclosure relate to LTM. In one aspect, a first network node may determine that one or more SCells associated with a target cell of an LTM cell switch are to be activated or deactivated, and transmit an indication of an activation or deactivation status of an SCell in the one or more SCells to a UE. The UE may activate or deactivate the SCell based on the activation or deactivation status of the SCell. With the solution, SCell activation and deactivation for LTM may be achieved.
Various aspects of the present application relate to methods and apparatuses of transmitting an event triggered layer-1 (L1) measurement report. According to an embodiment of the present application, a user equipment (UE) includes at least one memory and at least one processor coupled to the at least one memory and configured to cause the UE to: receive a first configuration related to at least one event for triggering a layer-1 (L1) measurement report, wherein the first configuration includes identifier (ID) information of the at least one event and a set of parameters associated with an entering condition and a leaving condition for the at least one event; evaluate whether the entering condition for the at least one event is satisfied within a first time duration; and evaluate whether the leaving condition for the at least one event is satisfied within a second time duration based on all beams of a candidate cell of the UE or a best beam of the candidate cell.
Various aspects of the present disclosure relate to a message transmission failure in ambient internet of things (A-IoT) system. In a solution of the disclosure, a first device receives, from a second device, a message 2 (Msg2) for a random access in ambient-Internet of Things (A-IoT) system. The first device transmits, based on the Msg 2, a message 3 (Msg3) for the random access to the second device. Then, the first device detects, within a monitoring window, a response message for the Msg 3. The response message comprises information on a transmission failure of the Msg 3.
The present disclosure relates to methods and apparatuses for access control and handover in a public network integrated non-public network. A first RAN node may: activate a cell to serve a first UE; and transmit information associated with a type of the cell to a second RAN node or to a core network node, wherein the type of the cell of the first RAN node comprises a non-closed access group cell, a CAG cell or a shared cell.
Various aspects of the present disclosure relate to a method and apparatus of supporting timely radio link control (RLC) retransmissions. An exemplary method may include: determining whether to trigger a RLC retransmission mechanism for data, including one or multiple of RLC retransmission or RLC polling based on delay status of the data before receiving a corresponding status report in RLC AM; and starting one or multiple of a first timer associated with the RLC retransmission for the data or a second timer associated with the RLC polling for the data in response to determining to trigger the RLC retransmission mechanism, wherein the first timer and the second timer refer to a same timer or separate timers.
Embodiments of the present disclosure relate to method and apparatus for secondary cell dormancy indication. According to some embodiments of the disclosure, a UE may: receive, from a BS, signaling indicating a set of cells; receive a DCI from the BS; determine that a set of fields in the DCI corresponding to a first cell of the set of cells is interpreted as indicating SCell dormancy for each SCell of the UE, wherein the first cell has a smallest serving cell index among cells indicated with an invalid FDRAvalue in the DCI; and switch, for an SCell of the UE, to a dormant BWP or an active BWP based on a corresponding bit of the set of fields.
Various aspects of the present disclosure relate to a method and apparatus of supporting non-access stratum (NAS) message delivery. An exemplary method performed by a NE may include: receiving, from a CN, NAS type related information associated with NAS messages to be delivered between a NF node and a UE via the NE; configuring a RB for NAS message delivery between the NE and the UE based on the NAS type related information; and performing the NAS message delivery between the NE and the UE via the RB.
Various aspects of the present disclosure relate to sensing signal communication. In an aspect, a user equipment (UE) receives, from a base station (BS), a configuration of at least one resource of the UE for sensing signal communication. Further, the UE receives, from the BS, a sensing indication that indicates to the UE to transmit a sensing signal to a sensing BS or a sensing UE. Moreover, the UE transmits the sensing signal via the at least one resource of the UE to the sensing BS or the sensing UE. The at least one resource of the UE for sensing signal communication is a common resource for sensing signal communication by the sensing BS or the sensing UE. In this way, it is allowed to achieve efficient sensing of the environment or object.
Various aspects of the present disclosure relate to AIoT assisted paging, such as AIoT assisted paging in a future mobile communication system. In an aspect, a first apparatus determines first information for assisting a paging procedure for a user equipment (UE), in which the first information comprises: (i) a UE identity (ID) or a device ID associated with the UE ID, and (ii) a base station ID or a reader ID associated with the base station ID. The first apparatus transmits the first information to a second apparatus for assisting the paging procedure.
The present disclosure relates to methods and apparatuses for dynamic activation of L1 measurement and report configuration. A UE may: transmit, to a BS, UE capability information associated with an activation of L1 measurement report related configurations; receive, from the BS, the L1 measurement report related configurations; receive, from the BS, an indication to activate or deactivate at least one configuration of the received L1 measurement report related configurations; and determine whether to trigger an L1 measurement report based on the received L1 measurement report related configurations and the indication.
Various aspects of the present disclosure relate to rate adaptation for a QoS flow. In one aspect, a first network node obtains at least one of a measured UL rate and a measured DL rate for a QoS flow. The first network node determines whether to adapt at least one of a UL rate and a DL rate for the QoS flow based on at least one of the measured UL rate and the measured DL rate for the QoS flow. If the first network node determines to adapt at least one of the UL rate and the DL rate for the QoS flow, the first network node transmits, to a UE, at least one of a reduced or increased UL rate and a reduced or increased DL rate for the QoS flow.
Various aspects of the present disclosure relate to midamble determination in an ambient Internet of things (A-IoT) system. In an aspect, a first device (for example, a reader) performs a first transmission related to A-IoT communication to a second device (for example, an A-IoT device). Moreover, the first device receives, from the second device, a second transmission. The second transmission comprises a plurality of data transmission parts and one or more midambles. A location of a midamble of the one or more midambles is determined based on a time duration for the second transmission or a number of the one or more midambles. In this way, it is allowed to improve communication performance in the A-IoT system.
Various aspects of the present disclosure relate to a UE, a processor for wireless communication, a network entity, and methods for supporting UE initiated beam management. In example method, the UE receives, from a network entity, one or more CSI report configurations for event triggered beam reporting. The UE determines at least one RS transmission occasion for computing L1-RSRP. The UE transmits, to the network entity, a beam report indicating one or more new beams for at least one of the one or more CSI report configurations. In this way, solutions are provided on the support of UE initiated beam management based on different events.
Embodiments of the present disclosure relate to method and apparatus for generating HARQ-ACK feedback for SCell dormancy indication by a DCI. According to some embodiments of the disclosure, a UE may: receive, from the BS, first DCI scheduling a second set of cells within the first set of cells with one or more data channels on each of the second set of cells; determine that a set of fields in the first DCI corresponding to a first cell of the first set of cells is interpreted as SCell dormancy indication for each SCell of the UE; generate HARQ-ACK feedback corresponding to the first cell for indicating reception of the SCell dormancy indication by the first DCI, in a second sub-codebook of a first HARQ-ACK codebook based on a number of TDRAs for the first cell indicated by the first DCI; and transmit the first HARQ-ACK codebook to the BS.
Various aspects of the present disclosure relate to methods and apparatuses for calibration reporting in a cell free massive multiple input multiple output (MIMO) system. Some implementations of the methods and apparatuses described herein may include a user equipment (UE) for wireless communication, comprising: at least one memory; and at least one processor coupled with the at least one memory and configured to cause the UE to: receive a configuration for a calibration report associated with one or more access point (AP) subsets or one or more AP clusters in a candidate AP cluster set, wherein the configuration includes a calibration measurement resource set; and transmit the calibration report based on measurement results on the calibration measurement resource set.
brevets
