CN110622541A - Configuration transmission - Google Patents

Abstract

One or more devices, systems, and/or methods are provided that facilitate transmission of one or more configurations. For example, the wireless node may receive a core configuration. The wireless node may receive the modified configuration. The wireless node may modify the core configuration based on the modified configuration to generate a modified configuration. The wireless node may perform measurements based on the modified configuration.

Description

Configuration transmission

Background

Communication links between wireless nodes may be facilitated by transmitting Reference Signals (RSs) between the wireless nodes (e.g., between a User Equipment (UE) and a network). For example, the network may send one or more RSs to the UE. The UE may perform Radio Resource Management (RRM) measurements using one or more RSs. Information about the communication link may be determined based on RRM measurements.

Disclosure of Invention

In accordance with the present disclosure, one or more devices and/or methods are provided that facilitate transmission of a configuration. In one example, a core configuration may be generated. A modified configuration corresponding to the core configuration may be generated. The core configuration and the modified configuration may be sent to the node.

In an example, a core configuration may be determined. A cell configuration corresponding to the cell may be determined. One or more differences between the core configuration and the cell configuration may be determined. The modified configuration may be generated based on one or more differences. The core configuration and the modified configuration may be sent to the node.

In an example, a core configuration and a modification configuration may be received from a node. The modified configuration may be generated based on modifying the core configuration. The first action may be performed based on the core configuration. The second action may be performed based on the modified configuration.

Drawings

Although the technology presented herein may be embodied in alternate forms, the specific embodiments shown in the drawings are only a few examples that are supplementary to the description provided herein. These examples should not be construed in a limiting manner, such as by limiting the appended claims.

FIG. 1A is a flow diagram illustrating an example method that facilitates transmission of a configuration.

FIG. 1B is a flow diagram illustrating an example method that facilitates transmission of a configuration.

FIG. 1C is a flow diagram illustrating an example method that facilitates receipt of a configuration.

FIG. 2 is a component block diagram illustrating an example system for facilitating transmission of a configuration.

FIG. 3 is a component block diagram illustrating an example system for facilitating transmission of a configuration.

FIG. 4 is a component block diagram illustrating an example system for facilitating transmission of a configuration.

Fig. 5 is a diagram illustrating an example of a core Channel State Information (CSI) Resource Signal (RS) configuration.

Fig. 6 is a diagram showing an example of a measurement object.

Fig. 7 is a diagram showing an example of a measurement object.

Fig. 8 is a diagram showing an example of a measurement object.

Fig. 9 is a diagram showing an example of a measurement object.

Fig. 10 is a diagram showing an example of a measurement object.

Fig. 11 is a diagram showing an example of a measurement object.

Fig. 12 is a diagram showing an example of a measurement object.

Fig. 13A is a component block diagram of an example system that illustrates multiple cells.

Fig. 13B is a component block diagram of an example system that illustrates multiple cells.

Fig. 14A is a component block diagram of an example system illustrating multiple CSI RS resources.

Fig. 14B is a component block diagram of an example system that illustrates multiple CSI RS resources.

Fig. 15 is a diagram showing an example of a core IDLE RS measurement configuration.

Fig. 16 is a diagram illustrating an example of one or more IDLE RS measurement configurations.

Fig. 17 is a diagram showing an example of a core IDLE RS measurement configuration.

Fig. 18 is a diagram showing an example of a cell IDLE RS measurement configuration.

Fig. 19A is a component block diagram of an example system illustrating multiple cells.

Fig. 19B is a component block diagram of an example system that illustrates multiple cells.

Fig. 20 is an illustration of a scenario involving an example configuration of a Base Station (BS) that may utilize and/or implement at least a portion of the techniques presented herein.

Fig. 21 is an illustration of a scenario involving an example configuration of a User Equipment (UE) that may utilize and/or implement at least a portion of the techniques presented herein.

Fig. 22 is an illustration of a scenario featuring an exemplary non-transitory computer-readable medium in accordance with one or more provisions set forth herein.

Detailed Description

The subject matter now will be described more fully hereinafter with reference to the accompanying drawings, which form a part hereof, and which show, by way of illustration, specific exemplary embodiments. This description is not intended to be an extensive or detailed discussion of known concepts. Details that are generally known to those of ordinary skill in the relevant art may have been omitted or may be processed in a summary manner.

The following subject matter may be embodied in various forms, such as methods, devices, components, and/or systems. Thus, the subject matter is not intended to be construed as limited to any of the example embodiments set forth herein. Rather, the example embodiments are provided for illustration only. Such embodiments may take the form of, for example, hardware, software, firmware, or any combination thereof.

One or more computing devices and/or techniques are provided that facilitate transmission of a configuration. For example, a User Equipment (UE) may connect (e.g., wirelessly communicate) to a network. The UE may perform cell-specific Radio Resource Management (RRM) measurements. RRM measurements may be used (e.g., and/or transmitted), for example, to enable the network to communicate with the UE reliably and/or at high data rates. The UE may perform RRM measurements based on the cell to derive one or more qualities of the cell (e.g., and/or signals corresponding to the cell). The UE may perform RRM measurements based on the cell using a configuration corresponding to the cell. The UE may perform RRM measurements (e.g., and/or perform cell detection) based on the cell based on a configuration contained within an IDLE Reference Signal (RS) (e.g., received from the network). The configuration may correspond to an IDLE RS measurement configuration in an IDLE (IDLE) state and/or an IDLE RS measurement configuration in a CONNECTED (CONNECTED) state. The UE may perform RRM measurements (e.g., and/or cell detection) based on the cell based on one or more other (e.g., additional) RSs. The one or more other RSs may include Channel State Information (CSI) RSs and/or other information. The CSI RS may include a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. The UE may perform RRM measurements based on the cell, manage (e.g., multi-antenna) beamforming applications, and/or manage a first layer (e.g., physical layer) and/or a second layer (e.g., Medium Access Control (MAC) layer) based on a low-layer CSI RS resource configuration for the first layer and/or the second layer. The UE may perform RRM measurements based on the cell, manage the third layer (e.g., Radio Resource Control (RRC) layer), and/or perform measurements for third layer mobility (e.g., and/or RRM mobility) based on the higher layer CSI RS resource configuration for the third layer. These RS configurations (e.g., their transmission, processing, etc.) may result in signaling overhead, especially when the UE is operating at high frequencies. The higher layer CSIRS resource configuration for the third layer may be the same, partially the same and/or different than the lower layer CSI RS resource configuration for the first layer and/or the second layer. Accordingly, the UE may use the lower layer CSI RS resource configuration for the first layer and/or the second layer as a configuration reference for the higher layer CSI RS resource configuration for the third layer to reduce signaling overhead. Alternatively and/or additionally, the UE may use the IDLE RS measurement configuration in the IDLE state as a configuration reference of the IDLE RS measurement configuration in the CONNECTED state to reduce signaling overhead.

An example method 100A that facilitates configuration transmissions from a first wireless node to a second wireless node is shown in fig. 1A. The first wireless node may be a network and/or a Base Station (BS) and the second wireless node may be a UE. The first wireless node may be required to send a configuration (e.g., CSI RS resource configuration, IDLE RS measurement configuration, etc.) to the second wireless node.

Thus, at 105A, the first wireless node generates a core configuration. In some examples, the core configuration may represent a configuration benchmark for one or more configurations. The one or more configurations may correspond to (e.g., particular and/or defined) configuration types of one or more layers and/or one or more states (e.g., respectively). For example, one or more lower-layer CSI RS resource configurations for a first layer and/or a second layer may correspond to a first configuration type, one or more higher-layer CSI RS resource configurations for a third layer may correspond to a second configuration type, one or more IDLE RS measurement configurations for an IDLE state may correspond to a third configuration type, one or more IDLE RS measurement configurations for a CONNECTED state may correspond to a fourth configuration type, and so on. In some examples, the core configuration may correspond to: a configuration type (e.g., the same as) one or more configurations (e.g., the same as) for which the core configuration represents a configuration reference. In some examples, the core configuration may correspond to: a configuration type that is (e.g., different from) one or more configurations (e.g., different) that the core configuration is configured to represent the configuration reference.

At 110A, the first wireless node generates a modified configuration corresponding to the core configuration. In some examples, the core configuration and/or the modified configuration corresponds to a (e.g., specific and/or defined) frequency. In some examples, the modified configuration may include overlay information (which corresponds to information contained within the core configuration) that may overlay at least some of the information included within the core configuration. In some examples, the modified configuration may include additional information that may be added and/or combined with information contained within the core configuration.

The modified configuration may correspond to a configuration type that may be the same or different from the configuration type of the core configuration. In some examples, the core configuration may include a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or the modified configuration may correspond to (e.g., and/or represent) a higher layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the core configuration may include an IDLE RS measurement configuration for an IDLE state and/or the modified configuration may correspond to (e.g., and/or represent) an IDLE RS measurement configuration for a CONNECTED state. Alternatively and/or additionally, the core configuration may include a first IDLE RS measurement configuration for IDLE state and/or the modified configuration may correspond to (e.g., and/or represent) a second IDLE RS measurement configuration for IDLE state. Alternatively and/or additionally, the core configuration may include a first IDLE RS measurement configuration for a CONNECTED state, and/or the modified configuration may correspond to (e.g., and/or represent) a second IDLE RS measurement configuration for the CONNECTED state.

At 115A, the first wireless node sends the core configuration and/or the modified configuration to the second wireless node.

Alternatively and/or additionally, the first wireless node may generate a second modified configuration corresponding to the core configuration. The first wireless node may send the second modified configuration to the second wireless node. In some examples, the second modified configuration may correspond to a core configuration (e.g., and/or a configuration type corresponding to a core configuration).

An example method 100B that facilitates configuration transmission from a first wireless node to a second wireless node is shown in fig. 1B. The first wireless node may be a network and/or the second wireless node may be a UE. Thus, at 105B, the first wireless node determines the core configuration. At 110B, the first wireless node determines a cell configuration corresponding to the cell.

The core configuration may represent a configuration reference for one or more configurations corresponding to one or more cells. The one or more configurations may include a cell configuration. The core configuration and/or one or more configurations may correspond to a (e.g., particular and/or defined) frequency. At 115B, the first wireless node determines one or more differences between the core configuration and the cell configuration. At 120B, the first wireless node generates a modified configuration based on the one or more differences. In some examples, the modified configuration may include overlay information (which corresponds to information included within the core configuration) that may overlay at least some of the information included within the core configuration. In some examples, the modified configuration may include additional information that may be added and/or combined with information contained within the core configuration.

The modified configuration may correspond to a configuration type that may be the same or different from the configuration type of the core configuration. In some examples, the core configuration may include a first higher layer CSI RS resource configuration and/or a modified configuration (e.g., and/or one or more configurations) for the third layer may correspond to (e.g., and/or represent) a second higher layer CSIRS resource configuration for the third layer.

In some examples, the core cell configuration corresponding to the second cell may include a core configuration. At 125B, the first wireless node sends the core configuration and the modified configuration to the second wireless node.

An example method 100C that facilitates receiving a configuration from a first wireless node at a second wireless node is shown in fig. 1C. The first wireless node may be a network and the second wireless node may be a UE. The second wireless node may perform one or more actions using one or more configurations from the first wireless node. Thus, at 105C, the second wireless node receives the core configuration and the modified configuration from the first wireless node. The core configuration may comprise information and/or the modification configuration may comprise overlay information that may overlay at least some of the information comprised in the core configuration and/or additional information that may be added and/or combined with the information comprised in the core configuration.

Alternatively and/or additionally, at 110C, the second wireless node generates a modified configuration by modifying the core configuration based on the modified configuration. The second wireless node may modify the information (e.g., of the core configuration) based on the coverage information (e.g., of the modified configuration) and/or the additional information to generate a modified configuration.

In some examples, the core configuration may represent a configuration reference for one or more configurations (e.g., a low-layer CSI RS resource configuration for a first layer and/or a second layer, a high-layer CSI RS resource configuration for a third layer, an IDLE RS measurement configuration for an IDLE state, an IDLE RS measurement configuration for a CONNECTED state, etc.) corresponding to a (e.g., particular and/or defined) configuration type. The one or more configurations may include a modified configuration.

In some examples, the core configuration may correspond to: a configuration type that is (e.g., different from) one or more configurations (e.g., different) that the core configuration is configured to represent the configuration reference. For example, the core configuration may include a lower layer CSI RS resource configuration for the first layer and/or the second layer, and/or the one or more configurations may include a higher layer CSI RS resource configuration for the third layer (e.g., and/or vice versa). Alternatively and/or additionally, the core configuration may include an IDLE RS measurement configuration for an IDLE state, and/or the one or more configurations may include an IDLE RS measurement configuration for a CONNECTED state (e.g., and/or vice versa).

In some examples, the core configuration may correspond to: a configuration type (e.g., the same as) one or more configurations (e.g., the same as) for which the core configuration represents a configuration reference. For example, the core configuration may include a first higher-layer CSI RS resource configuration for the third layer, and/or the one or more configurations may include a second higher-layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the core configuration may comprise a first IDLE RS measurement configuration for IDLE state, and/or the one or more configurations may comprise a second IDLE RS measurement configuration for IDLE state. Alternatively and/or additionally, the core configuration may include a first IDLE RS measurement configuration for a CONNECTED state, and/or the one or more configurations may include a second IDLE RS measurement configuration for a CONNECTED state.

At 115C, the second wireless node performs a first action based on the core configuration. In some examples, the core configuration may include a low-layer CSI RS resource configuration for (e.g., and/or management of) the first and/or second layer. The second wireless node may perform the first action based on the core configuration by using (e.g., and/or managing and/or performing RRM measurements based on) cells corresponding to the first layer and/or the second layer based on the core configuration.

Alternatively and/or additionally, the core configuration may include a higher layer CSI RS resource configuration for the third layer (e.g., and/or third layer mobility). The second wireless node may perform the first action by using (e.g., and/or managing and/or performing RRM measurements based on) the cell corresponding to the third layer based on the core configuration.

In some examples, the core configuration may include an IDLE RS measurement configuration for an IDLE state. Then, the second wireless node may perform the first action based on the core configuration by performing a first (e.g., RRM) measurement (e.g., and/or performing cell detection) in an IDLE state based on the core configuration and/or the corresponding cell. Alternatively and/or additionally, the core configuration may include an IDLE RS measurement configuration for a CONNECTED state. The second wireless node may then perform the first action based on the core configuration by performing a second (e.g., RRM) measurement (e.g., and/or performing cell detection) in the CONNECTED state based on the core configuration and/or the corresponding cell.

At 120C, the second wireless node performs a second action based on the modified configuration. In some examples, the modified configuration may include a low-level CSIRS resource configuration for (e.g., and/or management of) the first and/or second layers. The second wireless node may perform the second action based on the modified configuration by using (e.g., and/or based on managing and/or performing RRM measurements by) cells corresponding to the first layer and/or the second layer based on the modified configuration.

Alternatively and/or additionally, the modified configuration may include a higher layer CSI RS resource configuration for the third layer (e.g., and/or third layer mobility). The second wireless node may perform the second action based on the modified configuration by using (e.g., and/or based on managing and/or performing RRM measurements by) the cell corresponding to the third layer based on the modified configuration.

In some examples, the modified configuration may include an IDLE RS measurement configuration for an IDLE state. Then, the second wireless node may perform the second action based on the modified configuration by performing the first (e.g., RRM) measurements (e.g., and/or performing cell detection) in the IDLE state based on the modified configuration and/or the corresponding cell. Alternatively and/or additionally, the modified configuration may include an IDLE RS measurement configuration for a CONNECTED state. The second wireless node may then perform a second action based on the modified configuration by performing a second (e.g., RRM) measurement (e.g., and/or performing cell detection) in the CONNECTED state based on the modified configuration and/or the corresponding cell.

Alternatively and/or additionally, the second wireless node may receive the second modified configuration. Then, the second wireless node may generate a second modified configuration by modifying the core configuration based on the second modified configuration. In some examples, the second modified configuration may include a low layer CSI RS resource configuration for the first layer and/or the second layer. Then, the second wireless node may use (e.g., and/or manage and/or perform RRM measurements based on) the cells corresponding to the first layer and/or the second layer based on the second modified configuration.

Alternatively and/or additionally, the second modified configuration may comprise an IDLE state measurement configuration for the IDLE state. Then, the second wireless node may perform (e.g. RRM) measurements (e.g. and/or perform cell detection) in the IDLE state based on the second modified configuration and/or the corresponding cell.

The core configuration may correspond to a (e.g., specific and/or defined) frequency. The core configuration may represent a configuration reference for one or more configurations corresponding to the frequency. The one or more configurations may include a cell configuration corresponding to a cell. Thus, the second wireless node may use (e.g., and/or manage and/or perform RRM measurements based on) one or more cells based on the core configuration. The cell configuration may comprise a modified configuration. Thus, the second wireless node may use the cell based on the modified configuration (e.g., and/or manage and/or perform RRM measurements based thereon).

In some examples, the core cell configuration corresponding to the second cell may include a core configuration. Thus, the second wireless node may use the second cell (e.g., and/or manage and/or perform RRM measurements based thereon) based on the core configuration (e.g., the core cell configuration).

In some examples, the second wireless node may perform RRM measurements based on the cell to derive one or more qualities of the cell (e.g., and/or a signal corresponding to the cell). The second wireless node may perform RRM measurements based on (e.g., and/or using) at least one of a lower layer CSI RS resource configuration for the first layer and/or the second layer, a higher layer CSI RS resource configuration for the third layer, an IDLE RS measurement configuration for the IDLE state, and/or an IDLE RS measurement configuration for the CONNECTED state.

The first layer may include a physical layer. The physical layer may carry information such as power control measurements and/or cell search measurements (e.g., and/or other information and/or measurements). The second layer may include at least one of a MAC layer, a Radio Link Control (RLC) layer, and/or a packet data convergence control (PDCP) layer. The MAC layer may provide a connection between logical channels and transport channels and/or a connection between the physical layer and transport channels (e.g., and/or perform other functions). The third layer may include an RRC layer and/or a non-access stratum (NAS) protocol. The RRC layer may broadcast system information related to the NAS protocol (e.g., and/or perform other functions).

Fig. 2 illustrates an example of a system 200 for facilitating configuration transmissions from a first wireless node 205 (e.g., a network) to a second wireless node 210 (e.g., a UE). The first wireless node 205 may generate a core configuration 215 representing a configuration reference for one or more configurations. The first wireless node 205 may generate a modified configuration 220.

The first wireless node 205 may send the core configuration 215 and/or the modified configuration 220 to the second wireless node 210. In some examples, core configuration 215 and/or modification configuration 220 may be transmitted together and/or in a common signal. In some examples, the core configuration 215 and/or the modification configuration 220 may be transmitted separately and/or in separate signals.

The second wireless node 210 may generate a modified configuration 225 by modifying the core configuration 215 based on the modified configuration 220. Core configuration 215 may correspond to a first configuration type and/or modified configuration 225 may correspond to a second configuration type.

The first configuration type and the second configuration type may be different types. For example, the core configuration 215 includes a lower layer CSI RS resource configuration for the first layer and/or the second layer, and/or the modified configuration 225 may include a higher layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the core configuration 215 may include an IDLE RS measurement configuration for an IDLE state, and/or the modified configuration 225 may include an IDLE RS measurement configuration for a CONNECTED state.

Alternatively and/or additionally, the first configuration type and the second configuration type may be similar types and/or the same type. For example, the core configuration 215 may include a higher layer CSI RS resource configuration for the third layer, and/or the modified configuration 225 may include a higher layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the core configuration 215 may include an IDLE RS measurement configuration for a CONNECTED state, and/or the modified configuration 225 may include an IDLE RS measurement configuration for a CONNECTED state.

Fig. 3 illustrates an example of a system 300 for facilitating configuration transmissions from a first wireless node 305 (e.g., a network) to a second wireless node 310 (e.g., a UE). The first wireless node 305 may generate a core configuration 315, a modified configuration 320 and/or a second modified configuration 325. The core configuration 315 may represent a configuration reference for one or more configurations.

The first wireless node 305 may send the core configuration 315, the modified configuration 320, and/or the second modified configuration 325 to the second wireless node 310. In some examples, core configuration 315, modified configuration 320, and/or second modified configuration 325 may be transmitted together and/or in a common signal. In some examples, core configuration 315, modification configuration 320, and/or second modification configuration 325 may be transmitted separately and/or in separate signals. In some examples, at least some of the core configuration 315, the modified configuration 320, and/or the second modified configuration 325 may be transmitted in a first signal, while the remainder of the core configuration 315, the modified configuration 320, and/or the second modified configuration 325 may be transmitted in a second signal.

The second wireless node 310 may generate a modified configuration 330 by modifying the core configuration 315 based on the modified configuration 320. The second wireless node 310 may generate a second modified configuration 335 by modifying the core configuration 315 based on the second modified configuration.

The second modified configuration 335 may correspond to the first configuration type and/or the modified configuration 330 may correspond to the second configuration type. The first configuration type and the second configuration type may be different types. For example, the second modified configuration 335 may include a lower layer CSI RS resource configuration for the first layer and/or the second layer, and/or the modified configuration 330 may include an upper layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the second modified configuration 335 may include an IDLE RS measurement configuration for an IDLE state, and/or the modified configuration 330 may include an IDLE RS measurement configuration for a CONNECTED state.

Alternatively and/or additionally, the first configuration type and the second configuration type may be similar types and/or the same type. For example, the second modified configuration 335 may include a higher layer CSI RS resource configuration for the third layer, and/or the modified configuration 330 may include a higher layer CSI RS resource configuration for the third layer. Alternatively and/or additionally, the second modified configuration 335 may include an IDLE RS measurement configuration for a CONNECTED state, and/or the modified configuration 330 may include an IDLE RS measurement configuration for a CONNECTED state.

Fig. 4 illustrates an example of a system 400 for facilitating configuration transmissions from a first wireless node 405 (e.g., a network) to a second wireless node 410 (e.g., a UE). The first wireless node 405 may determine (e.g., and/or generate) a core configuration 415. Alternatively and/or additionally, the first wireless node 405 may determine (e.g., and/or generate) a cell configuration 425 corresponding to a cell. The first wireless node 405 may then use the analyzer 430 to determine one or more differences between the core configuration 415 and the cell configuration 425. The first wireless node 405 may then generate (e.g., and/or determine) a modified configuration 420 based on the one or more differences.

The first wireless node 405 may send the core configuration 415 and/or the modified configuration 420 to the second wireless node 410. In some examples, core configuration 415 and/or modification configuration 420 may be sent together and/or in a common signal. In some examples, core configuration 415 and/or modification configuration 420 may be sent separately and/or in separate signals.

Core configuration 415 may represent a configuration reference for one or more configurations corresponding to one or more cells, including cell configuration 425. Thus, the second wireless node 410 may generate the cell configuration 425 by modifying the core configuration 415 based on the modification configuration 420.

It may be appreciated that the core configuration, cell configuration, and/or modified configuration (e.g., as discussed with respect to fig. 1-4) may include a CSI RS resource configuration (e.g., core, carrier frequency, cell, higher layer, lower layer, etc.) and/or an IDLE RS measurement configuration (e.g., core, carrier frequency, cell, etc.) (e.g., as discussed with respect to fig. 5-19B).

Fig. 5 shows an example of a data structure 500 of a core CSI RS resource configuration. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a low-layer CSI RS resource configuration for the first layer and/or the second layer. Accordingly, a wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer based on the core CSI RS resource configuration.

The core CSI RS resource configuration may include one or more CSI RS resource settings. Thus, the core CSI RS resource configuration may include CSI RS resource settings identified as CSI resource setting Identification (ID) 1505. In some examples, CSI RS resource settings may be configured outside of the measurement objects and/or measurement configuration information (e.g., measConfig). Alternatively and/or additionally, the CSI RS resource setting may be configured within a dedicated physical configuration (e.g., a physical configdivided).

The CSI RS resource setting may include one or more CSI RS resources. Thus, the CSI RS resource setting may comprise a first CSI RS resource identified as CSI RS resource ID 1510 and/or a second CSI RS resource identified as CSI resource ID 2520.

The first CSI RS resource may include (e.g., and/or be configured with) first CSI RS resource information 515 and/or the second CSI RS resource may include (e.g., and/or be configured with) second CSI RS resource information 525. The first CSI RS resource information 515 and/or the second CSI RS resource information 525 may include at least one of a cell ID, a number of antenna ports, a configuration for time/frequency resource mapping, a timing configuration (e.g., time offset and/or periodicity), parameters for sequence generation, and/or other information (e.g., and/or parameters). The first CSI RS resource information 515 and/or the second CSI RS resource information 525 may include different (e.g., and/or the like) information.

In some examples, the core CSI RS resource configuration may represent a configuration reference for one or more CSI RS resource configurations (e.g., in one or more measurement objects).

Fig. 6 shows an example of a data structure 600 of a measurement object identified as a measurement object ID 1605. The measurement object may include information 610 and/or CSI RS resource configuration 615. Information 610 includes at least one of a carrier frequency, a measurement bandwidth, a timing configuration (e.g., time offset and/or periodicity), information of antenna ports, and/or other information (e.g., and/or parameters).

In some examples, the CSI RS resource configuration 615 may include one or more CSI RS resource setting IDs. The one or more CSI RS resource setting IDs may correspond to (e.g., link to) one or more CSI RS resource settings contained within the core CSI RS resource configuration. For example, CSI RS resource setting ID1 of CSI RS resource configuration 615 corresponds to (e.g., is linked to) a first CSI RS resource setting contained within the core CSI RS resource configuration. Accordingly, CSI RS resource setting ID3 of CSI RS resource configuration 615 corresponds to (e.g., is linked to) a second CSI RS resource setting contained within the core CSI RS resource configuration.

In some examples, CSI RS resource setting ID1 of CSI RS resource configuration 615 corresponds to (e.g., is linked to) a CSI RS resource setting contained within a core CSI RS resource configuration identified with the same CSI RS resource setting ID. Accordingly, CSI RS resource setting ID3 of CSI RS resource configuration 615 corresponds to (e.g., is linked to) a CSI RS resource setting contained within a core CSI RS resource configuration identified with the same CSI RS resource setting ID.

In some examples, the CSI RS resource configuration 615 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for the first layer and/or the second layer. Accordingly, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the CSI RS resource configuration 615 (e.g., and/or the measurement object) corresponding to the third layer. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. Thus, the wireless node may (e.g., be configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer and/or cells corresponding to the third layer based on the core CSI RS resource configuration.

In some examples, the CSI RS resource configuration 615 may include one or more modified configurations. In some examples, the wireless node may modify the core CSI RS resource configuration (e.g., to generate the CSIRS resource configuration 615) based on the one or more modified configurations. The modified configuration may include one or more CSI RS resource setting configurations, which may not be contained within the core CSI RS resource configuration. Thus, the CSI RS resource configuration 615 may correspond to a modified (e.g., added, supplemented, adjusted, etc.) version of the core CSI RS resource configuration. Alternatively and/or additionally, the CSI RS resource configuration 615 may include a zero modification configuration. Thus, the CSI RS resource configuration 615 may correspond to an unmodified version of the core CSI RS resource configuration.

Fig. 7 shows an example of a data structure 700 of a measurement object identified as a measurement object ID 1705. The measurement object may include information 710 and/or CSI RS resource configuration 715.

In some examples, CSI RS resource configuration 715 may include CSI RS resource setting ID1, which corresponds to (e.g., is linked to) a first CSI RS resource setting contained within the core CSI RS resource configuration. Alternatively and/or additionally, CSI RS resource configuration 715 may include CSI RS resource setting ID3, which corresponds to (e.g., is linked to) a second CSI RS resource setting contained within the core CSI RS resource configuration. In some examples, CSI RS resource configuration 715 may include a CSI RS resource setting ID1, which corresponds to (e.g., is linked to) a CSI RS resource setting contained within a core CSI RS resource configuration identified with the same CSI RS resource setting ID. Alternatively and/or additionally, CSI RS resource configuration 715 may include a CSI RS resource setting ID3, which corresponds to (e.g., is linked to) a CSI RS resource setting contained within a core CSI RS resource configuration identified with the same CSI RS resource setting ID.

In some examples, CSI RS resource configuration 715 may include one or more CSI RS resource IDs. The one or more CSI RS resource IDs may correspond to (e.g., link to) one or more CSI RS resources contained within the core CSI RS resource configuration. In some examples, the one or more CSI RS resource IDs contained within the CSI RS resource setting may correspond to one or more CSI RS resources identified by the same CSI RS resource ID contained within a corresponding CSI RS resource setting identified by the same CSI RS resource setting ID within the core CSI RS resource configuration. For example, CSI RS resource ID1 and/or CSIRS resource ID5 contained within the CSI RS resource setting identified with CSI RS resource setting ID1 of CSI RS resource configuration 715 may correspond to CSI RS resource ID1 and CSI RS resource ID5 contained within the CSI RS resource setting identified with CSI RS resource setting ID1 within the core CSI RS resource configuration.

In some examples, the CSI RS resource configurations 715 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for the first layer and/or the second layer. Thus, a wireless node (e.g., a UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the CSI RS resource configuration 715 (e.g., and/or the measurement object) using cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. Thus, the wireless node may (e.g., be configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer and/or cells corresponding to the third layer based on the core CSI RS resource configuration. In some examples, CSI RS resource configuration 715 may include a core CSI RS resource configuration.

Fig. 8 shows an example of a data structure 800 of a measurement object identified as a measurement object ID 1805. The measurement object may include information 810 and/or CSI RS resource configuration 815.

CSI RS resource configuration 815 may include a CSI RS resource setting ID1 corresponding to (e.g., linked to) a CSI RS resource setting contained within the core CSI RS resource configuration. In some examples, CSI RS resource configuration 815 may include CSI RS resource ID 2 corresponding to (e.g., linked to) CSI RS resources contained within the CSI RS resource setting.

In some examples, CSI RS resource configuration 815 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for a first layer and/or a second layer. Thus, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the CSI RS resource configuration 815 (e.g., and/or the measurement object) using cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. Thus, the wireless node may (e.g., be configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer and/or cells corresponding to the third layer based on the core CSI RS resource configuration.

In some examples, CSI RS resource configuration 815 may include one or more modified configurations. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. For example, CSI RS resource configuration 815 may include a modified configuration corresponding to CSI RS resource ID 2. The wireless node may modify CSI RS resources contained within the core CSI RS resource configuration based on the modified configuration (e.g., to generate CSI RS resource configuration 815). Thus, CSI RS resource configuration 815 may correspond to a modified version of the core CSI RS resource configuration.

In some examples, the modification configuration may include overlay information including one or more modification parameters. The one or more modified parameters may correspond to one or more parameters of CSI RS resource information of the CSI RS resource. For example, the modified parameter having the first value may correspond to a parameter of CSI RS resource information having the second value. Thus, the wireless node may modify the CSI RS resource information (e.g., and/or the core RS resource configuration) by modifying (e.g., changing) the second value of the CSI RS resource information to the first value.

For example, the CSI RS resource information may include at least one of: a first parameter comprising a number of antenna ports; a second parameter comprising a configuration for time/frequency resource mapping; a third parameter including a timing configuration (e.g., time offset and/or periodicity), a parameter used for sequence generation, and/or other parameters. Alternatively and/or additionally, modifying the configuration may include: a first modification parameter comprising a configuration for time/frequency resource mapping, and/or a second modification parameter comprising a timing configuration. Thus, the wireless node may modify the CSI RS resource information by modifying the value of the second parameter (e.g., the configuration for time/frequency resource mapping) to the value of the first modified parameter (e.g., corresponding to the second parameter). Alternatively and/or additionally, the wireless node may modify the CSI RS resource information by modifying a value of a third parameter (e.g., timing configuration) to a value of a second modified parameter (e.g., corresponding to the third parameter).

Fig. 9 shows an example of a data structure 900 of a measurement object identified as the measurement object ID 1905. The measurement object may include information 910 and/or CSI RS resource configuration 915.

CSI RS resource configuration 915 may include CSI RS resource ID1, which corresponds to (e.g., is linked to) a first CSI RS resource contained within the core CSI RS resource configuration. Alternatively and/or additionally, CSI RS resource configuration 915 may include CSI RS resource ID 2, which corresponds to (e.g., is linked to) a second CSI RS resource contained within the core CSI RS resource configuration. Alternatively and/or additionally, CSI RS resource configuration 915 may include CSI RS resource ID 4, which corresponds to (e.g., is linked to) a third CSI RS resource contained within the core CSI RS resource configuration.

In some examples, the CSI RS resource configuration 915 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for the first layer and/or the second layer. Accordingly, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the CSI RS resource configuration 915 (e.g., and/or the measurement object) using cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. Thus, the wireless node may (e.g., be configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer and/or cells corresponding to the third layer based on the core CSI RS resource configuration.

In some examples, the CSI RS resource configuration 915 may include one or more modified configurations. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. For example, CSI RS resource configuration 915 may include a first modified configuration corresponding to CSI RS resource ID 2 (e.g., and/or corresponding to a second CSI RS resource). The wireless node may modify the second CSI RS resource contained within the core CSI RS resource configuration based on the first modified configuration (e.g., to generate CSI RS resource configuration 915). Alternatively and/or additionally, the CSI RS resource configuration 915 may include a second modified configuration corresponding to CSI RS resource ID 4 (e.g., and/or corresponding to a third CSI RS resource). The wireless node may modify the third CSI RS resource contained within the core CSI RS resource configuration based on the second modified configuration (e.g., to generate CSI RS resource configuration 915). Thus, the CSI RS resource configuration 915 may correspond to a modified version of the core CSI RS resource configuration.

In some examples, the first modified configuration may include overlay information including one or more modification parameters. For example, the first modified configuration may include a first modified parameter (e.g., a configuration for time/frequency resource mapping) corresponding to a first parameter (e.g., a configuration for time/frequency resource mapping) of second CSI RS resource information of the second CSI RS resource. Thus, the wireless node may modify the second CSI RS resource information by modifying (e.g., changing) the value of the first parameter to the value of the first modified parameter. Alternatively and/or additionally, the first modification configuration may include a second modification parameter (e.g., timing configuration) corresponding to a second parameter (e.g., timing configuration) of the second CSI RS resource information. Thus, the wireless node may modify the second CSI RS resource information by modifying (e.g., changing) the value of the second parameter to the value of the second modified parameter.

In some examples, the second modified configuration may include overlay information including one or more modification parameters. For example, the second modified configuration may include a third modified parameter (e.g., number of antenna ports) corresponding to a third parameter (e.g., number of antenna ports) of third CSI RS resource information of the third CSI RS resource. Thus, the wireless node may modify the third CSI RS resource information by modifying (e.g., changing) the value of the third parameter to the value of the third modified parameter. Alternatively and/or additionally, the second modified configuration may include a fourth modified parameter (e.g., configuration for time/frequency resource mapping) corresponding to a fourth parameter (e.g., configuration for time/frequency resource mapping) of the third CSI RS resource information. Thus, the wireless node may modify the third CSI RS resource information by modifying (e.g., changing) the value of the fourth parameter to the value of the fourth modified parameter.

Thus, the wireless node may modify the second CSI RS resource information of the second CSI RS resource (e.g., identified by CSI RS resource ID 2) and/or the third CSI RS resource information of the third CSI RS resource (e.g., identified by CSI RS resource ID 4) without modifying the first CSI RS resource information of the first CSI RS resource (e.g., identified by CSI RS resource ID 1).

Fig. 10 shows an example of a data structure 1000 of a measurement object identified as a measurement object ID 11005. The measurement object may include information 1010 and/or CSI RS resource configuration 1015. The CSI RS resource configuration 1015 may include a CSI RS resource ID1 corresponding to (e.g., linked to) the CSI RS resources contained within the core CSI RS resource configuration.

In some examples, the CSI RS resource configuration 1015 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for a first layer and/or a second layer. Thus, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the CSI RS resource configuration 1015 (e.g., and/or measurement objects) using cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer. In some examples, the core CSI RS resource configuration may include (e.g., and/or be configured to) a lower layer CSI RS resource configuration for the first layer and/or the second layer and/or a higher layer CSI RS resource configuration for the third layer. Thus, the wireless node may (e.g., be configured to) use (e.g., and/or manage and/or perform RRM measurements based on) cells corresponding to the first layer and/or the second layer and/or cells corresponding to the third layer based on the core CSI RS resource configuration.

In some examples, the CSI RS resource configuration 1015 may include one or more modified configurations. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. For example, the CSI RS resource configuration 1015 may include a modified configuration corresponding to CSI RS resource ID1 (e.g., and/or corresponding to CSI RS resources). The wireless node may modify CSI RS resources within the core CSI RS resource configuration based on the modification configuration (e.g., to generate a CSI RS resource configuration 1015). Thus, the CSI RS resource configuration 1015 may correspond to a modified version of the core CSI RS resource configuration.

The CSI RS resource information of the CSI RS resource may include one or more parameters corresponding to the one or more values. The modification configuration may include overlay information that includes one or more modification parameters corresponding to the one or more modification values (e.g., corresponding to the one or more parameters). The wireless node may modify the CSI RS resource information by modifying (e.g., and/or changing) one or more values (e.g., each of them) (e.g., all of them) corresponding to the one or more parameters to one or more modified values corresponding to the one or more modified parameters.

Fig. 11 shows an example of a data structure 1100 of a measurement object identified as measurement object ID 11105. The measurement object may include information 1110, a core CSI RS resource configuration 1115, a first cell CSI RS resource configuration 1125 (identified as cell ID 11120) and/or a second cell CSI RS resource configuration 1135 (identified as cell ID 21130).

In some examples, information 1110 includes at least one of: carrier frequency, measurement bandwidth, timing configuration (e.g., time offset and/or periodicity), information of antenna ports, and/or other information (e.g., and/or parameters). In some examples, at least one of the core CSI RS resource configuration 1115, the first cell CSI RS resource configuration 1125, and/or the second cell CSI RS resource configuration 1135 may correspond to a carrier frequency.

In some examples, the core CSI RS resource configuration 1115 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for a first layer and/or a second layer. Accordingly, a wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the core CSI RS resource configuration 1115 (e.g., and/or measurement objects) with cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer.

Core CSI RS resource configuration 1115 may include one or more CSI RS resource settings. Thus, core CSI RS resource configuration 1115 may include a first CSI RS resource setting identified as CSI resource setting ID1 and/or a second CSI RS resource setting identified as CSI resource setting ID 2. The first CSI RS resource setting and/or the second CSI RS resource setting may include one or more CSI RS resources. Thus, the first CSI RS resource setting may comprise the first CSI RS resource identified as CSI RS resource ID1 and/or the second CSI RS resource setting may comprise the second RS resource identified as CSI RS resource ID 1. The first CSI RS resource may be configured with first CSI RS resource information and/or the second CSI RS resource may be configured with second CSI RS resource information.

The first cell CSI RS resource configuration 1125 may correspond to the cell corresponding to the cell ID 11120. The first cell CSI RS resource configuration 1125 may include a CSI RS resource setting ID1 corresponding to (e.g., linked to) the first CSI RS resource setting within the core CSI RS resource configuration 1115. The first cell CSI RS resource configuration 1125 may include a CSI RS resource ID1 of a first CSI RS resource corresponding to (e.g., linked to) a first CSI RS resource setting within the core CSI RS resource configuration 1115.

The second cell CSI RS resource configuration 1135 may correspond to a cell corresponding to cell ID 21130. The second cell CSI RS resource configuration 1135 may include CSI RS resource setting 2 corresponding to (e.g., linked to) a second CSI RS resource setting within the core CSI RS resource configuration 1115. The second cell CSI RS resource configuration 1135 may include a CSIRS resource ID1 of the first CSI RS resource corresponding to (e.g., linked to) the second CSI RS resource setting within the core CSI RS resource configuration 1115.

In some examples, the first cell CSI RS resource configuration 1125 and/or the second cell CSI RS resource configuration 1135 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for the first layer and/or the second layer. Thus, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the cells corresponding to the third layer and/or the cells corresponding to the first layer and/or the second layer based on the first cell CSI RS resource configuration 1125 and/or the second cell CSI RS resource configuration 1135 (e.g., and/or the measurement object).

In some examples, the first cell CSI RS resource configuration 1125 may include a modified configuration corresponding to the first CSI RS resource. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. The wireless node may modify the first CSI RS resource within the core CSI RS resource configuration 1115 based on the modification configuration (e.g., to generate a first cell CSI RS resource configuration 1125). Thus, the first cell CSI RS resource configuration 1125 may correspond to a modified version of the core CSI RS resource configuration 1115.

In some examples, the modification configuration may include overlay information including one or more modification parameters. For example, the modified configuration may include a first modified parameter (e.g., a configuration for time/frequency resource mapping) corresponding to a first parameter (e.g., a configuration for time/frequency resource mapping) of first CSI RS resource information of the first CSI RS resource. Thus, the wireless node may modify the first CSI RS resource information by modifying (e.g., changing) the value of the first parameter to the value of the first modified parameter. Alternatively and/or additionally, the modification configuration may include a second modification parameter (e.g., timing configuration) corresponding to a second parameter (e.g., timing configuration) of the first CSI RS resource information. Thus, the wireless node may modify the first CSI RS resource information by modifying (e.g., changing) the value of the second parameter to the value of the second modified parameter.

Thus, the first cell CSI RS resource configuration 1125 may correspond to a modified version of the core CSI RS resource configuration 1115, and/or the second cell CSI RS resource configuration 1135 may correspond to an unmodified version of the core CSI RS resource configuration 1115.

Fig. 12 shows an example of a data structure 1200 of a measurement object identified as measurement object ID 11205. The measurement object may include information 1210, a first cell CSI RS resource configuration 1220 identified as cell ID 11215, a second cell CSI RS resource configuration 1230 identified as cell ID 21225, and/or a third cell CSI RS resource configuration 1240 identified as cell ID 31235.

In some examples, the information 1210 includes at least one of: carrier frequency, measurement bandwidth, timing configuration (e.g., time offset and/or periodicity), information of antenna ports, and/or other information (e.g., and/or parameters). In some examples, at least one of the first cell CSI RS resource configuration 1220, the second cell CSI RS resource configuration 1230, and/or the third cell CSIRS resource configuration 1240 may correspond to a carrier frequency.

In some examples, the first cell CSI RS resource configuration 1220 may include (e.g., and/or be configured to) a higher layer CSI RS resource configuration for a third layer and/or a lower layer CSI RS resource configuration for the first layer and/or the second layer. Thus, the wireless node (e.g., UE) may be (e.g., configured to) use (e.g., and/or manage and/or perform RRM measurements based on) the first cell CSI RS resource configuration 1220 (e.g., and/or measurement object) using cells corresponding to the third layer and/or cells corresponding to the first layer and/or the second layer.

The first cell CSI RS resource configuration 1220 may include one or more CSI RS resource settings including one or more CSI resources. Thus, the first cell CSI RS resource configuration 1220 may include a CSI RS resource setting identified as CRS resource setting ID1 and/or a CSI RS resource identified as CSI RS resource ID 1.

Fig. 13A shows an example of a system 1300A of multiple cells corresponding to multiple cell CSI RS resource configurations. The plurality of cell CSI RS resource configurations may correspond to (e.g., specific and/or defined) frequencies. System 1300A may be applied to data structure 1200 shown in fig. 12. A first cell CSI RS resource configuration 1220 of the plurality of cell CSI RS resource configurations corresponding to the first cell 11035 a may correspond to (e.g., serve) a core CSI RS resource configuration.

In some examples, the first cell CSI RS configuration 1220 may represent a reference configuration for one or more of a plurality of cell CSI RS resource configurations (e.g., in addition to the first cell CSI RS resource configuration 1220). The one or more cell CSI RS resource configurations may include a second cell CSI RS resource configuration 1230 corresponding to the second cell 21310 a and/or a third cell CSI RS resource configuration 1240 corresponding to the third cell 31315A. Thus, the second cell CSI RS resource configuration 1230 may include a CSI RS resource setting ID1 corresponding to (e.g., linked to) a CSI RS resource setting of the first cell CSI RS configuration 1220, and/or a CSI RS resource ID1 corresponding to (e.g., linked to) a CSI RS resource of the first cell CSI RS configuration 1220. The third cell RS resource configuration 1240 may include a resource setting ID1 corresponding to (e.g., linked to) a CSI RS resource setting, and/or a CSI RS resource ID1 corresponding to (e.g., linked to) a CSI RS resource (e.g., corresponding to the first cell CSI RS resource configuration 1220).

In some examples, the second cell CSI RS resource configuration 1230 may include a modified configuration corresponding to CSI RS resources. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. The wireless node may modify CSI RS resources within the first cell CSI RS resource configuration 1220 based on the modified configuration (e.g., to generate a second cell CSI RS resource configuration 1230). Thus, the second cell CSI RS resource configuration 1230 may correspond to a modified version of the first cell CSI RS resource configuration 1220. The third cell CSI RS resource configuration 1240 may correspond to an unmodified version of the first cell CSI RS resource configuration 1220.

Fig. 13B illustrates an example of a system 1300B of multiple cells corresponding to multiple cell CSI RS resource configurations. The plurality of cell CSI RS resource configurations may correspond to (e.g., specific and/or defined) frequencies. In some examples, a cell CSI RS resource configuration of the plurality of cell CSI RS resource configurations may represent a configuration reference for (e.g., no more than) one (e.g., next and/or subsequent) cell CSI RS resource configuration of the plurality of cell CSI RS resource configurations. System 1300B may be applied to data structure 1200 shown in fig. 12. A first cell CSI RS resource configuration 1220 of the plurality of cell CSI RS resource configurations corresponding to the first cell 11035B may represent a configuration reference for a second cell CSI RS resource configuration 1230 of the plurality of cell CSI RS resource configurations corresponding to the second cell 21310B (e.g., next and/or subsequent). The second cell CSI RS resource configuration 1230 may represent a configuration reference for a third cell CSI RS resource configuration 1240 (e.g., next and/or subsequent) of the plurality of cell CSI RS resources corresponding to the third cell 31315B.

Thus, the second cell CSI RS resource configuration 1230 may include: CSI resource setting ID1 corresponding to (e.g., linked to) the CSI RS resource setting of the first cell CSI RS configuration 1220, and/or CSI RS resource ID1 corresponding to (e.g., linked to) the CSI RS resource of the first cell CSI RS configuration 1220. The third cell RS resource configuration 1240 may include: a resource setting ID1 of a second CSI RS resource setting corresponding to (e.g., linked to) the second cell CSI RS resource configuration 1220, and/or a CSI RS resource ID1 of a second CSI RS resource corresponding to (e.g., linked to) the second cell CSI RS resource configuration 1230.

In some examples, the second cell CSI RS resource configuration 1230 may include a modified configuration corresponding to CSI RS resources. The modified configuration may include one or more overlaid and/or additional CSI RS resource configurations. The wireless node may modify CSI RS resources within the first cell CSI RS resource configuration 1220 based on the modified configuration (e.g., to generate a second cell CSI RS resource configuration 1230). Thus, the second cell CSI RS resource configuration 1230 may correspond to a modified version of the first cell CSI RS resource configuration 1220. The third cell CSI RS resource configuration 1240 may correspond to an unmodified version of the second cell CSI RS resource configuration 1230.

Fig. 14A shows an example of a system 1400A of multiple CSI RS resources. The plurality of CSI RS resources may correspond to (e.g., specific and/or defined) frequency and/or cell and/or CSI RS resource settings. Alternatively and/or additionally, the plurality of CSI RS resources may be contained within one or more measurement objects (e.g., and/or cells). The plurality of CSI RS resources may include a first CSI RS resource 11405A. In some examples, the first CSI RS resource 11405A may correspond to (e.g., serve as) a core CSI RS resource. In some examples, the first CSI RS resource 11405A may represent a configuration reference for one or more of a plurality of cell CSI RS resources (e.g., in addition to the first cell CSI RS resource 11405A). The one or more CSI RS resources may include a second CSI RS resource 21410A and/or a third CSI RS resource 31415A.

Fig. 14B illustrates an example of a system 1400B of multiple CSI RS resources. The plurality of CSI RS resources may correspond to (e.g., specific and/or defined) frequency and/or cell and/or CSI RS resource settings. Alternatively and/or additionally, the plurality of CSI RS resources may be contained within one or more measurement objects (e.g., and/or cells). In some examples, a CSI RS resource of the plurality of CSI RS resources may represent a configuration reference for (e.g., no more than) one (e.g., next and/or subsequent) CSI RS resource of the plurality of CSI RS resources. For example, the plurality of CSI RS resources may include a first CSI RS resource 11405B. The first CSI RS resource 11405B may represent a configuration reference (e.g., next and/or subsequent) for the second CSI RS resource 21410B. The second CSI resource 31415B may represent a configuration for a third CSI RS resource 31415B (e.g., next and/or subsequent).

Fig. 15 shows an example of a data structure 1500 for a core IDLE RS measurement configuration. In some examples, the core IDLE RS measurement configuration may include (e.g., and/or be configured to) an IDLE RS measurement configuration for IDLE states. Thus, the wireless node (e.g., UE) may then perform a first (e.g., RRM) measurement (e.g., and/or perform cell detection) in the IDLE state based on the core IDLE RS measurement configuration and/or corresponding cell. Alternatively and/or additionally, the core IDLE RS measurement configuration may include (e.g., and/or be configured to) an IDLE RS measurement configuration for a CONNECTED state. The wireless node may then perform a second (e.g., RRM) measurement (e.g., and/or perform cell detection) in the CONNECTED state based on the core IDLE RS measurement configuration and/or the corresponding cell.

The core IDLE RS measurement configuration may include one or more carrier frequency IDLE RS measurement configurations. Thus, the core IDLE RS measurement configuration may comprise a first IDLE RS measurement configuration 1505 corresponding to a first frequency and/or a second IDLE RS measurement configuration 1510 corresponding to a second frequency. The first frequency may be the same or different from the second frequency.

The first IDLE RS measurement configuration 1505 may be configured with first IDLE RS information and/or the second IDLE RS measurement configuration 1510 may be configured with second IDLE RS information.

The first IDLE RS information and/or the second IDLE RS information may include at least one of: IDLE RS periodicity, IDLE RS timing window (e.g., timing offset and/or duration), IDLE RS information actually sent, and/or other information (e.g., and/or parameters). The first IDLE RS information and/or the second IDLE RS information may include different (e.g., or similar) information.

In some examples, the core IDLE RS measurement configuration may represent a configuration reference for one or more IDLE RS measurement configurations.

Fig. 16 shows an example of a data structure 1600 for one or more IDLE RS measurement configurations. The one or more IDLE RS measurement configurations may include a carrier frequency 1IDLE RS measurement configuration 1605 corresponding to carrier frequency 1, and/or a carrier frequency 2IDLE RS measurement configuration 1610 corresponding to carrier frequency 2, and/or a frequency 3IDLE RS measurement configuration 1615 with a carrier corresponding to carrier frequency 3. Carrier frequency 1 may correspond to (e.g., be linked to) a first frequency of a first IDLE RS measurement configuration contained within a core IDLE RS measurement configuration. Carrier frequency 2 may correspond to (e.g., be linked to) a second frequency of a second IDLE RS measurement configuration contained within the core IDLE RS measurement configuration. The first frequency may be the same or different from the second frequency. Carrier frequency 3 may correspond to additional carrier frequencies within the core IDLE RS measurement configuration in addition to the first carrier frequency and the second carrier frequency.

In some examples, carrier frequency 1IDLE RS measurement configuration 1605 may include a first modified configuration corresponding to the first IDLE RS measurement configuration. The wireless node may modify the first IDLE RS measurement configuration within the core IDLE RS measurement configuration based on the first modified configuration (e.g., to generate carrier frequency 1IDLE RS measurement configuration 1605). Thus, carrier frequency 1IDLE RS measurement configuration 1605 may correspond to a modified version of the first IDLE RS measurement configuration.

In some examples, the first modified configuration may include overlay information including one or more modification parameters. For example, the first modified configuration may include a first modified parameter (e.g., IDLE timing window) corresponding to a first parameter (e.g., IDLE timing window) of the first IDLE RS information of the first IDLE RS measurement configuration. Thus, the wireless node may modify the first IDLE RS information by modifying (e.g., changing) the value of the first parameter to the value of the first modified parameter.

In some examples, carrier frequency 2IDLE RS measurement configuration 1610 may include a second modified configuration corresponding to a second IDLE RS measurement configuration. The wireless node may modify a second IDLE RS measurement configuration within the core IDLE RS measurement configuration based on the second modified configuration (e.g., to generate carrier frequency 2IDLE RS measurement configuration 1610). Thus, carrier frequency 2IDLE RS measurement configuration 1610 may correspond to a modified version of the second IDLE RS measurement configuration.

In some examples, the second modified configuration may include overlay information including one or more modification parameters. For example, the second modified configuration may include a second modified parameter (e.g., actually transmitted IDLE RS information) corresponding to a second parameter (e.g., actually transmitted IDLE RS information) of the second IDLE RS information of the second IDLE RS measurement configuration. Thus, the wireless node may modify the second IDLERS information by modifying (e.g., changing) the value of the second parameter to the value of the second modified parameter.

In some examples, the third modified configuration may add a third IDLE RS measurement configuration 1615 corresponding to a third frequency (e.g., carrier frequency 3). The third IDLE RS measurement configuration 1615 may be configured with third IDLE RS information. The third IDLERS information may include: at least one of IDLE RS periodicity, IDLE RS timing window (e.g., timing offset and/or duration), actually transmitted IDLE RS information, and/or other information (e.g., and/or parameters). Thus, the wireless node may add a third IDLE RS configuration in addition to the first and second IDLE RS configurations.

In some examples, carrier frequency 1IDLE RS measurement configuration 1605 and/or carrier frequency 2IDLE RS measurement configuration 1610 may include (e.g., and/or be configured to) an IDLE RS measurement configuration for IDLE states. Thus, the wireless node (e.g., UE) may then perform a first (e.g., RRM) measurement (e.g., and/or perform cell detection) in an IDLE state based on the carrier frequency 1IDLE RS measurement configuration 1605, the frequency 2IDLE RS measurement configuration 1610, and/or the corresponding cell. Alternatively and/or additionally, carrier frequency 1IDLE RS measurement configuration 1605 and/or carrier frequency 2IDLE RS measurement configuration 1610 may include (e.g., and/or be configured to) an IDLE RS measurement configuration for a CONNECTED state. The wireless node may then perform a second (e.g., RRM) measurement (e.g., and/or perform cell detection) in the CONNECTED state based on carrier frequency 1IDLE RS measurement configuration 1605, carrier frequency 2IDLE RS measurement configuration 1610, and/or the corresponding cell.

Fig. 17 shows an example of a data structure 1700 of a core IDLE RS measurement configuration 1705 and/or a cell IDLE RS measurement configuration 1710 identified as cell ID 1. Cell IDLE RS measurement configuration 1710 may correspond to carrier frequency 1, which corresponds to (e.g., is linked to) the frequency of core IDLE RS measurement configuration 1705.

In some examples, the cell IDLE RS measurement configuration 1710 may include a modified configuration corresponding to the core IDLE RS measurement configuration 1705. The wireless node may modify the core IDLE RS measurement configuration 1705 based on the modification configuration (e.g., to generate a cell IDLE RS measurement configuration 1710). Thus, the cell IDLE RS measurement configuration 1710 may correspond to a modified version of the core IDLE RS measurement configuration 1705.

In some examples, the modification configuration may include overlay information including one or more modification parameters. For example, the modification configuration may include a modification parameter (e.g., actually transmitted IDLE RS information) corresponding to a parameter of the core IDLE RS information (e.g., actually transmitted IDLE RS information) of the core IDLE RS measurement configuration 1705. Thus, the wireless node may modify the core IDLE RS information by modifying (e.g., changing) the value of the parameter to a modified value of the parameter.

In some examples, the core IDLE RS measurement configuration 1705 and/or the cell IDLE RS measurement configuration 1710 may include (e.g., and/or be configured to) an IDLE RS measurement configuration for an IDLE state. Thus, the wireless node (e.g., UE) may then perform a first (e.g., RRM) measurement (e.g., and/or perform cell detection) in an IDLE state based on the core IDLE RS measurement configuration 1705, the cell IDLE RS measurement configuration 1710, and/or the corresponding cell. Alternatively and/or additionally, the core IDLE RS measurement configuration 1705 and/or the cell IDLE RS measurement configuration 1710 may correspond to (e.g., and/or be configured to) an IDLE RS measurement configuration for a CONNECTED state. The wireless node may then perform a second (e.g., RRM) measurement (e.g., and/or perform cell detection) in the CONNECTED state based on the core IDLE RS measurement configuration 1705, the cell IDLE RS measurement configuration 1710, and/or the corresponding cell.

Fig. 18 shows an example of a data structure 1800 of a first cell IDLE RS measurement configuration 1810 identified as cell ID1, a second cell IDLE RS measurement configuration 1815 identified as cell ID 2 and/or a third cell IDLE RS measurement configuration 1820 identified as cell ID 3. The first, second, and/or third cell IDLE RS measurement configurations 1810, 1815, 1820 may correspond to a carrier frequency 11805.

Fig. 19A shows an example of a system 1900A of multiple cells corresponding to multiple cell IDLE RS measurement configurations. The plurality of cell IDLE RS measurement configurations may correspond to a (e.g., particular and/or defined) frequency. System 1900A may be applied to data structure 1800 shown in fig. 18. A first cell IDLE RS measurement configuration 1810 of the plurality of cell IDLE RS measurement configurations corresponding to the first cell 11905 a may correspond to (e.g., serve as) a core IDLE RS measurement configuration.

In some examples, the first cell IDLE RS measurement configuration 1810 may represent a configuration benchmark for one or more of a plurality of cell IDLE RS measurement configurations (e.g., different from the first cell IDLE RS measurement configuration 1810). The one or more cell IDLE RS measurement configurations may include a second cell IDLE RS measurement configuration 1815 corresponding to the second cell 21910A, and/or a third cell IDLE RS measurement configuration 1820 corresponding to the third cell 31915A. Thus, the second cell IDLE RS measurement configuration 1815 may correspond to (e.g., link to) the first cell IDLE RS measurement configuration 1810. Alternatively and/or additionally, the third cell IDLE RS measurement configuration 1820 may correspond to (e.g., be linked to) the first cell IDLE RS measurement configuration 1810.

In some examples, the second cell IDLE RS measurement configuration 1815 may include a first modified configuration corresponding to the first cell IDLE RS measurement configuration 1810. The wireless node may modify the first cell IDLE RS measurement configuration 1810 (e.g., to generate a second cell IDLE RS measurement configuration 1815) based on the first modified configuration. Thus, the second cell IDLE RS measurement configuration 1815 may correspond to a modified version of the first cell IDLE RS measurement configuration 1810. The third cell IDLE RS1820 configuration may correspond to an unmodified version of the first cell IDLE RS measurement configuration 1810.

Fig. 19B shows an example of a system 1900B of multiple cells corresponding to multiple cell IDLE RS measurement configurations. The plurality of cell IDLE RS measurement configurations may correspond to a (e.g., particular and/or defined) frequency. In some examples, a cell IDLE RS measurement configuration of the plurality of cell IDLE RS measurement configurations may represent a configuration reference of (e.g., no more than) one (e.g., next and/or subsequent) cell IDLE RS measurement configuration of the plurality of cell IDLE RS measurement configurations. System 1900B may be applied to data structure 1800 shown in fig. 18. The first cell IDLE RS measurement configuration 1810 of the plurality of cell IDLE RS measurement configurations corresponding to the first cell 11905B may represent a configuration reference for a second cell IDLE RS measurement configuration 1815 of the plurality of cell IDLE RS measurement configurations corresponding to the second cell 21910B. The second cell IDLE RS measurement configuration 1815 may represent a configuration reference of a (e.g., next and/or subsequent) third cell IDLE RS measurement configuration 1820 corresponding to the third cell 31915B, of the plurality of cell IDLE RS measurement configurations.

In some examples, the second cell IDLE RS measurement configuration 1815 may include a second modified configuration corresponding to the first cell IDLE RS measurement configuration 1810. The wireless node may modify the first cell IDLE RS measurement configuration 1810 based on the second modified configuration (e.g., to generate a second cell IDLE RS measurement configuration 1815). Thus, the second cell IDLE RS measurement configuration 1815 may correspond to a modified version of the first cell IDLE RS measurement configuration 1810. The third cell IDLE RS1820 configuration may correspond to an unmodified version of the second cell IDLE RS measurement configuration 1815.

Fig. 20 presents a schematic architecture diagram 2000 of a base station 2050 (e.g., a node) that may utilize at least a portion of the techniques provided herein. Such base stations 2050 may vary widely in configuration and/or capabilities (alone or in combination with other base stations, nodes, terminal units, and/or servers, etc.) to provide services such as at least some of one or more of still other disclosed techniques, scenarios, etc. For example, the base station 2050 can connect one or more User Equipment (UE) to a (e.g., wireless and/or wired) network (e.g., which can connect to and/or include one or more other base stations), such as a Code Division Multiple Access (CDMA) network, a Time Division Multiple Access (TDMA) network, a Frequency Division Multiple Access (FDMA) network, an orthogonal FDMA (ofdma) network, a single-carrier FDMA (SC-FDMA) network, and the like. The network may implement radio technologies such as Universal Terrestrial Radio Access (UTRA), CDMA2000, global system for mobile communications (GSM), evolved UTRA (E-UTRA), IEEE 802.11, IEEE 802.16, IEEE802.20, Flash-OFDM, etc. The base station 2050 and/or the network may communicate using a standard such as Long Term Evolution (LTE).

The base station 2050 may include one or more (e.g., hardware) processors 2010 to process instructions. One or more processors 2010 may optionally include multiple cores; one or more coprocessors, such as math coprocessors or integrated Graphics Processing Units (GPUs); and/or one or more levels of local cache memory. The base station 2050 may include a memory 2002 that stores various forms of application programs such as an operating system 2004; one or more base station applications 2006; and/or various forms of data such as database 2008 and/or file systems, etc. The base station 2050 can include various peripheral components such as a wired and/or wireless network adapter 2014 that can connect to a local area network and/or a wide area network; one or more storage components 2016 such as a hard disk drive, a solid State Storage Device (SSD), a flash memory device and/or a magnetic and/or optical disk reader; and/or other peripheral components.

The base station 2050 may include a motherboard featuring one or more communication buses 2012, the communication buses 2012 interconnecting the processor 2010, the memory 2002 and/or various peripherals using various bus technologies such as variants of a serial or parallel AT attachment (ATA) bus protocol, a Universal Serial Bus (USB) protocol, and/or a small computer system interface (SCI) bus protocol. In a multi-bus scenario, the communication bus 2012 may interconnect the base station 2050 with at least one other server. Other components (although not shown in the schematic diagram 2000 of fig. 20) optionally included in the base station 2050 include a display; a display adapter such as a Graphics Processing Unit (GPU); input peripherals such as a keyboard and/or mouse; and/or a flash memory device that can store basic input/output system (BIOS) routines that help to boot the base station 2050 to a ready state, etc.

The base station 2050 may operate in various physical enclosures such as a desktop or tower and/or may be integrated with a display into an "all-in-one" device. The base station 2050 may be mounted horizontally and/or in a cabinet or rack and/or may simply comprise a set of interconnected components. The base station 2050 may include a dedicated and/or shared power supply 2018 that provides and/or regulates power for other components. The base station 2050 may provide power to and/or receive power from another base station and/or a server and/or other devices. The base station 2050 may include a shared and/or dedicated climate control unit 2020 that regulates climate characteristics such as temperature, humidity, and/or airflow. Many such base stations 2050 may be configured and/or adapted to utilize at least a portion of the techniques presented herein.

Fig. 21 presents a schematic architecture diagram 2100 of a User Equipment (UE)2150 (such as a node) upon which at least a portion of the techniques presented herein may be implemented. Such UEs 2150 may vary widely in configuration and/or capabilities in order to provide various functionality to the user. The UE2150 may be provided in various forms, such as a mobile phone (such as a smartphone); a desktop or tower workstation; an "all-in-one" device integrated with the display 2108; a notebook computer, a tablet computer, a convertible tablet computer or a palm device; wearable devices (such as may be mounted in headphones, glasses, earplugs, and/or watches, and/or integrated with clothing); and/or a component of a piece of furniture, such as a table top, and/or other devices such as a vehicle or a home. The UE2150 may serve users in various roles, such as a phone, a workstation, a kiosk, a media player, a gaming device, and/or a home appliance.

The UE2150 may include one or more (such as hardware) processors 2110 that process instructions. The one or more processors 2110 may optionally include multiple cores; one or more coprocessors such as math coprocessors or integrated Graphics Processing Units (GPUs); and/or one or more levels of local cache memory. The UE2150 may include a memory 2101 that stores various forms of applications, such as an operating system 2103; one or more user applications 2102, such as document applications, media applications, file and/or data access applications, communication applications, such as web browsers and/or email clients, utilities and/or games; and/or drivers for various peripheral devices. The UE2150 can include various peripheral components, such as a wired and/or wireless network adapter 2106 that can connect to a local area network and/or a wide area network; one or more output components, such as a display 2108 coupled to a display adapter (optionally including a Graphics Processing Unit (GPU)), a sound adapter coupled to speakers, and/or a printer; input devices for receiving input from a user, touch sensitive components such as a keyboard 2111, mouse, microphone, camera, and/or display 2108; and/or environmental sensors, such as a GPS receiver 2119 that detects the position, velocity, and/or acceleration of the UE2150, a compass that detects the physical orientation of the UE2150, an accelerometer, and/or a gyroscope. Other components that may optionally be included with the UE2150 (although not shown in the schematic architecture diagram 2100 of fig. 21) include one or more storage components, such as a hard disk drive, a solid State Storage Device (SSD), a flash memory device, and/or a magnetic and/or optical disk reader; a flash memory device that may store basic input/output system (BIOS) routines that help to boot the UE2150 into a ready state; and/or a climate control unit that adjusts climate characteristics such as temperature, humidity, and airflow.

The UE2150 may include a motherboard featuring one or more communication buses 2112 that interconnect the processor 2110, memory 2101, and/or various peripherals using various bus technologies, such as variants of serial or parallel AT attachment (ATA) bus protocols, a Unified Serial Bus (USB) protocol, and/or a small computer system interface (SCI) bus protocol. The UE2150 can include a dedicated and/or shared power source 2118 that supplies and/or regulates power for other components, and/or a battery 2104 that stores power for use when the UE2150 is not connected to a source of power via the power source 2118. The UE2150 may provide power to and/or receive power from other client devices.

Fig. 22 is an illustration of a scenario 2200 involving an exemplary non-transitory computer-readable medium 2202. The non-transitory computer-readable medium 2202 may include processor-executable instructions 2212 that, when executed by the processor 2216, cause performance (such as by the processor 2216) of at least some of the provisions herein. The non-transitory computer-readable medium 2202 may include a memory semiconductor (such as a semiconductor utilizing Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), and/or Synchronous Dynamic Random Access Memory (SDRAM) technology), a platter of a hard disk drive, a flash memory device, or a magnetic or optical disk (such as a Compact Disk (CD), a Digital Versatile Disk (DVD), and/or a floppy disk). The example non-transitory computer-readable medium 2202 stores computer-readable data 2204, which computer-readable data 2204 is expressed when read 2206 by a reader 2210 of a device 2208 (such as a read head of a hard disk drive or a read operation invoked on a solid state storage device). In some embodiments, the processor-executable instructions 2212, when executed, cause performance of operations, such as at least some of the example method 100A of fig. 1A, the example method 100B of fig. 1B, the example method 100C of fig. 1C, for example. In some embodiments, the processor-executable instructions 2212 are configured to cause an implementation of a system and/or scenario, such as, for example, the example system 200 of fig. 2, the example system 300 of fig. 3, the example system 400 of fig. 4, the example system corresponding to the data structure 500 of fig. 5, the example system corresponding to the data structure 600 of fig. 6, the example system corresponding to the data structure 700 of fig. 7, the example system corresponding to the data structure 800 of fig. 8, the example system corresponding to the data structure 900 of fig. 9, the example system corresponding to the data structure 1000 of fig. 10, the example system corresponding to the data structure 1100 of fig. 11, the example system corresponding to the data structure 1200 of fig. 12, the example system 1300A of fig. 13A, the example system 1300B of fig. 13B, the example system 1400A of fig. 14A, the example system 1400B of fig. 14B, the example system corresponding to the data structure 1500 of fig. 15, the example system, At least some of the example systems corresponding to the data structure 1600 of FIG. 16, the example systems corresponding to the data structure 1700 of FIG. 17, the example systems corresponding to the data structure 1800 of FIG. 18, the example system 1900A of FIG. 19A, and/or the example system 1900B of FIG. 19B.

As used in this application, the terms "component," "module," "system," "interface," and/or the like are generally intended to refer to a computer-related entity, either hardware, a combination of hardware and software, or software in execution. For example, a component can be, but is not limited to being, a process running on a processor, an object, an executable, a thread of execution, a program, and/or a computer. For example, both an application running on a controller and the controller can be a component. One or more components can reside within a process and/or thread of execution and a component can be localized on one computer and/or distributed between two or more computers (such as nodes).

Unless otherwise stated, "first," "second," and/or the like are not intended to imply temporal, spatial, ordering, and the like. Rather, these terms are merely used as identifiers, names, etc. of features, elements, items, etc. For example, the first object and the second object typically correspond to object a and object B or two different or the same objects or equivalent objects.

Moreover, "examples" are used herein to mean serving as an example, illustration, or the like, and are not necessarily advantageous. As used herein, "or" is intended to mean an inclusive "or" rather than an exclusive "or". In addition, the use of "a" and "an" in this application is generally to be construed to mean "one or more" unless specified otherwise or clear from context to be directed to a singular form. Furthermore, at least one of A and/or B, etc. typically represents A or B or both A and B. Furthermore, to the extent that the terms "includes," has, "" with, "" has, "and/or variants thereof are used in either the detailed description or the claims, such terms are intended to be inclusive in a manner similar to the term" comprising.

Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing at least some of the claims.

Furthermore, the claimed subject matter may be implemented as a method, apparatus, or article of manufacture using standard programming and/or engineering techniques to produce software, firmware, hardware, or any combination thereof to control a computer (such as a node) to implement the disclosed subject matter. The term "article of manufacture" as used herein is intended to encompass a computer program accessible from any computer-readable device, carrier, or media. Of course, many modifications may be made to this configuration without departing from the scope or spirit of the claimed subject matter.

Various operations of the embodiments and/or examples are provided herein. The order of some or all of the operations described herein should not be construed as to imply that these operations are necessarily order dependent. Alternative orderings will be appreciated by those skilled in the art having the benefit of this description. Further, it should be understood that not all operations are necessarily present in each embodiment and/or example provided herein. Moreover, it should be understood that not all operations are necessary in some embodiments and/or examples.

Further, although the disclosure has been shown and described with respect to one or more implementations, equivalent alterations and modifications will occur to others skilled in the art based upon a reading and understanding of this specification and the annexed drawings. The present disclosure includes all such modifications and alterations, and is limited only by the scope of the appended claims. In particular regard to the various functions performed by the above described components (e.g., elements, resources, etc.), the terms used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (e.g., that is functionally equivalent), even though not structurally equivalent to the disclosed structure. In addition, while a particular feature of the disclosure may have been disclosed with respect to only one of several implementations, such feature may be combined with one or more other features of the other implementations as may be desired and advantageous for any given or particular application.

Claims (38)

1. A method, comprising:

generating a core configuration;

generating a modified configuration corresponding to the core configuration; and is

The core configuration and the modified configuration are sent to the node.

2. The method of claim 1, wherein

The core configuration represents a configuration reference of a lower layer configuration corresponding to at least one of the first layer or the second layer and a higher layer configuration corresponding to the third layer.

3. The method of claim 2, comprising:

generating a second modified configuration corresponding to the core configuration, the second modified configuration representing a lower-level configuration; and is

The second modified configuration is sent to the node.

4. The method of claim 1, wherein

The core configuration comprises a low-level configuration corresponding to at least one of a first level or a second level; and is

The modified configuration represents a higher layer configuration corresponding to a third layer.

5. The method of claim 1, wherein

The core configuration represents a configuration reference of an idle state measurement configuration corresponding to an idle state and a connection state measurement configuration corresponding to a connection state.

6. The method of claim 5, comprising:

generating a second modified configuration corresponding to the core configuration, the second modified configuration representing an idle state measurement configuration; and is

Sending the second modified configuration to a node.

7. The method of claim 1, wherein

The core configuration comprises an idle state measurement configuration corresponding to an idle state; and is

The modified configuration represents a connection state measurement configuration corresponding to a connection state.

8. The method of claim 1, wherein

The core configuration comprises a first idle state measurement configuration corresponding to an idle state; and is

The modified configuration represents a second idle state measurement configuration corresponding to an idle state.

9. The method of claim 1, wherein

The core configuration comprises a first connection state measurement configuration corresponding to a connection state; and is

The modified configuration represents a second connection state measurement configuration corresponding to the connection state.

10. The method of claim 1, wherein

The core configuration includes information; and is

The modified configuration includes overlay information corresponding to the information.

11. The method of claim 1, wherein

The core configuration corresponds to a frequency; and is

The modified configuration corresponds to the frequency.

12. A method, comprising:

determining a core configuration;

determining a cell configuration corresponding to a cell;

determining one or more differences between a core configuration and a cell configuration;

generating a modified configuration based on the one or more differences; and is

The core configuration and the modified configuration are sent to the node.

13. The method of claim 12, wherein

The core configuration represents a configuration reference for cell configuration.

14. The method of claim 12, wherein

The core configuration represents a configuration reference for one or more cell configurations corresponding to one or more cells, the one or more cell configurations corresponding to a frequency.

15. The method of claim 12, wherein

The core configuration includes a second cell configuration corresponding to a second cell, the second cell configuration representing a configuration reference for the cell configuration.

16. The method of claim 12, wherein

The core configuration includes a second cell configuration corresponding to a second cell, the second cell configuration representing a configuration reference for one or more cell configurations corresponding to one or more cells, the one or more cell configurations corresponding to a frequency.

17. The method of claim 12, wherein

The core configuration comprises a first higher layer configuration corresponding to a third layer; and is

The modified configuration represents a second higher-level configuration corresponding to a third level.

18. The method of claim 12, wherein

The core configuration includes information; and is

The modified configuration includes overlay information corresponding to the information.

19. A method, comprising:

receiving a core configuration and a modified configuration from a node;

generating a modified configuration by modifying a core configuration based on the modified configuration;

performing a first action based on the core configuration; and is

A second action is performed according to the modified configuration.

20. The method of claim 19, wherein

The core configuration represents a configuration reference of a lower layer configuration corresponding to at least one of the first layer or the second layer and a higher layer configuration corresponding to the third layer.

21. The method of claim 19, wherein

The core configuration comprises a low-level configuration corresponding to at least one of a first level or a second level;

the first action comprises using at least one of a first layer or a second layer based on a core configuration;

the modified configuration comprises a higher layer configuration corresponding to a third layer; and is

The second action includes using a third layer based on the modified configuration.

22. The method of claim 19, wherein

The core configuration comprises a low-level configuration corresponding to at least one of a first level or a second level;

the first action includes performing a first measurement based on a cell corresponding to at least one of a first layer or a second layer in accordance with the core configuration;

the modified configuration comprises a higher layer configuration corresponding to a third layer; and is

The second action includes performing a second measurement based on a cell corresponding to a third layer in accordance with the modified configuration.

23. The method of claim 19, wherein

The core configuration comprises a first higher layer configuration corresponding to a third layer;

the second action comprises performing a first measurement based on a cell corresponding to a third layer in accordance with the core configuration;

the modified configuration comprises a second higher-layer configuration corresponding to a third layer; and is

The second action includes performing a second measurement based on a cell corresponding to a third layer in accordance with the modified configuration.

24. The method of claim 19, comprising:

receiving a second modified configuration; and is

Generating a second modified configuration by modifying the core configuration based on a second modified configuration.

25. The method of claim 24, wherein

The second modified configuration comprises a lower-layer configuration corresponding to at least one of the first layer or the second layer; and is

The first action includes using at least one of the first layer or the second layer based on the second modified configuration.

26. The method of claim 19, wherein

The core configuration represents a configuration reference of an idle state measurement configuration corresponding to an idle state and a connection state measurement configuration corresponding to a connection state.

27. The method of claim 19, wherein

The core configuration comprises an idle state measurement configuration corresponding to an idle state;

the first action comprises performing a first measurement in an idle state based on a core configuration;

the modified configuration comprises a connection state measurement configuration corresponding to a connection state; and is

The second action includes performing a second measurement in the connected state based on the modified configuration.

28. The method of claim 19, wherein

The core configuration comprises a first idle state measurement configuration corresponding to an idle state;

the first action comprises performing a first measurement in an idle state based on a core configuration;

the modified configuration comprises a second idle state measurement configuration corresponding to an idle state; and is

The second action includes performing a second measurement in an idle state based on the modified configuration.

29. The method of claim 19, wherein

The core configuration comprises a first connection state measurement configuration corresponding to a connection state;

the first action comprises performing a first measurement in a connected state based on a core configuration;

the modified configuration comprises a second connection state measurement configuration corresponding to a connection state; and is

The second action includes performing a second measurement in the connected state based on the modified configuration.

30. The method of claim 24, wherein

The second modified configuration comprises an idle state measurement configuration corresponding to an idle state; and is

The first action includes performing a first measurement in an idle state based on the second modified configuration.

31. The method of claim 19, wherein

The core configuration includes information;

the modified configuration includes coverage information corresponding to the information;

modifying the core configuration based on the coverage information.

32. The method of claim 31, comprising:

modifying the information based on the coverage information to generate a modified configuration.

33. The method of claim 19, wherein

The core configuration corresponds to a frequency;

the modified configuration corresponds to the frequency; and is

The modified configuration corresponds to the frequency.

34. The method of claim 19, wherein

The core configuration represents a configuration reference of one or more configured cells corresponding to one or more cells, the one or more configured cells corresponding to a frequency; and is

The first action includes using the one or more cells based on a core configuration.

35. The method of claim 19, wherein

The modified configuration comprises a cell configuration corresponding to a cell; and is

The second action includes using a cell based on a cell configuration.

36. The method of claim 19, wherein

The core configuration comprises a cell configuration corresponding to a cell, which represents a configuration reference for one or more cell configurations corresponding to one or more cells, the one or more cell configurations corresponding to a frequency;

the first action comprises using a cell based on a cell configuration;

the modified configuration comprises a second cell configuration corresponding to a second cell; and is

The second action includes using a second cell based on a second cell configuration.

37. A communication device, comprising:

a processor; and

a memory comprising processor-executable instructions that, when executed by a processor, cause performance of the method of any one of claims 1-36.

38. A non-transitory computer readable medium having stored thereon processor-executable instructions that, when executed, cause performance of the method of any one of claims 1-36.