WO2024031443A1 - 信息指示、信息接收装置以及方法 - Google Patents
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Definitions
- the embodiments of this application relate to the field of communication technology.
- Network energy conservation is of great significance to environmental sustainability, reducing environmental impact (greenhouse gas emissions) and saving operating costs.
- 5G fifth generation mobile communication technology
- 5G fifth generation mobile communication technology
- the current Release 18 (R18) phase introduces the topic of network energy conservation.
- Network energy-saving technologies can be divided into time domain/frequency domain/air domain/energy domain types, but in actual applications, it is more likely to be used in combination with two or more types of energy-saving technologies.
- energy saving can be achieved by adjusting airspace elements.
- the airspace elements here include logical antenna ports, transmitting and receiving unit (TXRU), transmitting chain (Tx chain), array antenna factors, etc.; in terms of time domain energy-saving technology, cell ON/OFF can be used or the public channel can be reduced /Signal transmission method to achieve energy saving; in terms of frequency domain energy saving technology, energy saving can be achieved through partial bandwidth (bandwidth part, BWP) switching and other methods.
- TXRU transmitting and receiving unit
- Tx chain transmitting chain
- BWP bandwidth part
- CSI channel state information
- CSI- RS channel state information reference signals
- BWP partial bandwidth
- embodiments of the present application provide an information indication, information receiving device and method.
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/or BWP switching.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- an information indication device which is applied to network equipment.
- the device includes:
- a sending unit that sends indication information to the terminal device, where the indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference Signal
- an information receiving device is provided, applied to terminal equipment, and the device includes:
- a receiving unit that receives the instruction information
- Determining unit which determines according to the indication information: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference signal (CSI-RS) resource update ; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference signal
- an information indication method is provided, which is applied to network equipment.
- the information indication method includes:
- the network device changes the service mode
- the network device sends indication information to the terminal device, wherein the indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference Signal
- an information receiving method is provided and applied to a terminal device.
- the information receiving method includes:
- the terminal device receives indication information
- the terminal device determines according to the indication information: channel state information (CSI) measurement method update; and/or channel state information (CSI) reporting update; and/or channel state information reference signal (CSI-RS) resource update ; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference signal
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS Resource updates; and/or, BWP switching.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- Figure 1 is a schematic diagram of a communication system according to an embodiment of the present application.
- Figure 2 is a schematic diagram of an information indication method according to an embodiment of the present application.
- Figure 3 is an example diagram of instruction information according to an embodiment of the present application.
- Figure 4 is an example diagram of CSI reporting according to an embodiment of the present application.
- Figure 5 is an example diagram of CSI-RS resource update according to the embodiment of this application.
- Figure 6 is an example diagram of CSI-RS port update according to an embodiment of the present application.
- Figure 7 is a schematic diagram of an information receiving method according to an embodiment of the present application.
- Figure 8 is a schematic diagram of the information indication device in the embodiment of the present application.
- Figure 9 is a schematic diagram of an information receiving device in an embodiment of the present application.
- Figure 10 is a schematic diagram of the structure of a network device according to an embodiment of the present application.
- Figure 11 is a schematic structural diagram of a terminal device according to an embodiment of the present application.
- the terms “first”, “second”, etc. are used to distinguish different elements from the title, but do not indicate the spatial arrangement or temporal order of these elements, and these elements should not be used by these terms. restricted.
- the term “and/or” includes any and all combinations of one or more of the associated listed terms.
- the terms “comprises,” “includes,” “having” and the like refer to the presence of stated features, elements, elements or components but do not exclude the presence or addition of one or more other features, elements, elements or components.
- the term “communication network” or “wireless communication network” may refer to a network that complies with any of the following communication standards, such as Long Term Evolution (LTE), Long Term Evolution Enhanced (LTE-A, LTE-Advanced), Broadband Code Division Multiple Access (WCDMA, Wideband Code Division Multiple Access), High-Speed Packet Access (HSPA, High-Speed Packet Access), etc.
- LTE Long Term Evolution
- LTE-A Long Term Evolution Enhanced
- LTE-A Long Term Evolution Enhanced
- WCDMA Broadband Code Division Multiple Access
- WCDMA Wideband Code Division Multiple Access
- High-Speed Packet Access High-Speed Packet Access
- HSPA High-Speed Packet Access
- communication between devices in the communication system can be carried out according to any stage of communication protocols, which may include but are not limited to the following communication protocols: 1G (generation), 2G, 2.5G, 2.75G, 3G, 4G, 4.5G and 5G. , New Wireless (NR, New Radio), etc., and/or other communication protocols currently known or to be developed in the future.
- Network device refers to a device in a communication system that connects a terminal device to a communication network and provides services to the terminal device.
- Network equipment may include but is not limited to the following equipment: base station (BS, Base Station), access point (AP, Access Point), transmission and reception point (TRP, Transmission Reception Point), broadcast transmitter, mobile management entity (MME, Mobile Management Entity), gateway, server, wireless network controller (RNC, Radio Network Controller), base station controller (BSC, Base Station Controller), etc.
- the base station may include but is not limited to: Node B (NodeB or NB), evolved Node B (eNodeB or eNB), 5G base station (gNB), IAB host, etc.
- NodeB Node B
- eNodeB or eNB evolved Node B
- gNB 5G base station
- IAB host etc.
- it may also include Remote Radio Head (RRH, Remote Radio). Head), remote wireless unit (RRU, Remote Radio Unit), relay or low-power node (such as femeto, pico, etc.).
- RRH Remote Radio Head
- RRU Remote Radio Unit
- relay or low-power node such as femeto, pico, etc.
- base station may include some or all of their functions, each of which may provide communications coverage to a specific geographic area.
- the term "cell” may refer to a base station and/or its coverage area, depending on the context in which the term is used.
- the term "user equipment” (UE, User Equipment) or “terminal equipment” (TE, Terminal Equipment or Terminal Device) refers to a device that accesses a communication network through a network device and receives network services.
- Terminal equipment can be fixed or mobile, and can also be called mobile station (MS, Mobile Station), terminal, subscriber station (SS, Subscriber Station), access terminal (AT, Access Terminal), station, etc.;
- MS Mobile Station
- SS Subscriber Station
- AT Access Terminal
- station Access Terminal
- the terminal equipment may include but is not limited to the following equipment: cellular phone (Cellular Phone), personal digital assistant (PDA, Personal Digital Assistant), wireless modem, wireless communication equipment, handheld device, machine-type communication equipment, laptop computer, Cordless phones, wearables, smartphones, smart watches, digital cameras, and more.
- cellular phone Cellular Phone
- PDA Personal Digital Assistant
- wireless modem wireless communication equipment
- handheld device machine-type communication equipment
- laptop computer Cordless phones
- wearables smartphones
- smart watches digital cameras, and more.
- terminal devices can also be machines or devices for monitoring or measuring.
- they can include but are not limited to: Machine Type Communication (MTC) terminals, Vehicle-mounted communication terminals, industrial wireless equipment, surveillance cameras, device-to-device (D2D, Device to Device) terminals, machine-to-machine (M2M, Machine to Machine) terminals, etc.
- MTC Machine Type Communication
- D2D Device to Device
- M2M Machine to Machine
- network side refers to one side of the network, which may be a certain base station or a certain core network device, or may include one or more of the above network devices.
- user side or “terminal side” or “terminal device side” refers to the side of the user or terminal, which may be a certain UE or may include one or more terminal devices as above.
- device can refer to network equipment or terminal equipment.
- uplink control signal and “uplink control information (UCI, Uplink Control Information)” or “physical uplink control channel (PUCCH, Physical Uplink Control Channel)” can be interchanged without causing confusion.
- uplink data signal and “uplink data information” or “physical uplink shared channel (PUSCH, Physical Uplink Shared Channel)” can be interchanged, “cell” and “carrier” and “serving cell” and “carrier component” Can be interchanged.
- downlink control signal” and “downlink control information (DCI, Downlink Control Information)” or “physical downlink control channel (PDCCH, Physical Downlink Control Channel)” are interchangeable, and the terms “downlink data signal” and “downlink data information” are interchangeable.
- Physical Downlink Shared Channel PDSCH, Physical Downlink Shared Channel
- DCI and DCI format format
- sending or receiving PUSCH can be understood as sending or receiving uplink data carried by PUSCH
- sending or receiving PUCCH can be understood as sending or receiving uplink information (e.g. UCI) carried by PUCCH
- sending or receiving PRACH can be understood as sending or receiving The preamble carried by PRACH
- sending or receiving PDSCH can be understood as sending or receiving downlink data carried by PDSCH
- sending or receiving PDCCH can be understood as sending or receiving downlink information (e.g. DCI) carried by PDCCH.
- the high-level signaling may be, for example, Radio Resource Control (RRC) signaling; the RRC signaling may include, for example, an RRC message (RRC message), including, for example, a master information block (MIB), system information (system information), Dedicated RRC message; or RRC information element (RRC information element, RRC IE); or the information domain included in the RRC message or RRC information element (or the information domain included in the information domain).
- RRC Radio Resource Control
- the high-level signaling may also be, for example, Medium Access Control layer (Medium Access Control, MAC) signaling; or it may be called MAC control element (MAC control element, MAC CE).
- Medium Access Control layer Medium Access Control, MAC
- MAC control element MAC control element
- Figure 1 is a schematic diagram of a communication system according to an embodiment of the present application, schematically illustrating a terminal device and a network device as an example.
- the communication system 100 may include a network device 101 and terminal devices 102 and 103.
- Figure 1 only takes two terminal devices and one network device as an example for illustration, but the embodiment of the present application is not limited thereto.
- eMBB enhanced mobile broadband
- mMTC massive machine type communication
- URLLC Ultra-Reliable and Low -Latency Communication
- URLLC Ultra-Reliable and Low -Latency Communication
- Figure 1 shows that both terminal devices 102 and 103 are within the coverage of the network device 101, but the application is not limited thereto. Neither of the two terminal devices 102 and 103 may be within the coverage range of the network device 101, or one terminal device 102 may be within the coverage range of the network device 101 and the other terminal device 103 may be outside the coverage range of the network device 101.
- the current Release 18 (R18) phase introduces the topic of network energy conservation.
- Network energy-saving technologies can be divided into time domain/frequency domain/air domain/energy domain types, but in actual applications, it is more likely to be used in combination with two or more types of energy-saving technologies.
- energy saving can be achieved by adjusting airspace elements.
- the airspace elements here include logical antenna ports, transmitting and receiving unit (TXRU), transmitting chain (Tx chain), array antenna factors, etc.; in terms of time domain energy-saving technology, cell ON/OFF can be used or public signals can be reduced Transmission method to achieve energy saving; in terms of frequency domain energy saving technology, energy saving can be achieved through partial bandwidth (bandwidth part, BWP) switching and other methods.
- TXRU transmitting and receiving unit
- Tx chain transmitting chain
- BWP bandwidth part
- the network device enters an energy-saving mode (power-saving mode or sleep mode).
- power-saving mode When network equipment changes between normal (ordinary) mode and energy-saving mode, it will affect terminal-related processing, including channel state information (CSI) measurement method updates, channel state information (CSI) reporting updates, channel state information reference signals (CSI- RS) resource update, partial bandwidth (BWP) switching, etc.
- CSI channel state information
- CSI- RS channel state information reference signals
- BWP partial bandwidth
- At least one energy-saving mode or normal (ordinary) mode can be changed by adjusting the number of airspace elements.
- the terminal device may change the CSI measurement method; in addition, In principle, the number of airspace elements cannot be less than the number of CSI-RS ports, otherwise the CSI-RS cannot be configured normally; in the process of achieving energy saving by adjusting the number of airspace elements, when the energy-saving mode is turned on or off, the number of airspace elements may be smaller than the CSI -The number of RS ports, and thus the CSI-RS time, frequency and space resources need to be updated.
- embodiments of the present application provide an information indication, information receiving device and method.
- the embodiment of this application provides an information indication method, which is explained from the network device side.
- FIG. 2 is a schematic diagram of an information indication method according to an embodiment of the present application. As shown in Figure 2, the method includes:
- Network equipment changes service mode
- the network device sends indication information to the terminal device, where the indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference Signal
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- the service mode includes a normal mode and/or at least one energy saving mode.
- “at least one energy-saving mode” may include at least one of the following modes: “energy-saving mode”, “light energy-saving mode”, “deep energy-saving mode”, or “energy-saving transition mode”, etc.
- This application does not limit this ;
- the above-mentioned “normal mode” can also be replaced by “normal mode”;
- the above-mentioned “energy-saving mode” can also be replaced by expressions such as “power-saving mode” or “sleep mode” or "non-energy-saving mode” or “off mode”. This application There are no restrictions on this.
- the service mode can be changed by changing the "airspace elements” or changing the "antenna mode". For example, by turning off part of the "airspace elements", the network changes from “normal mode” to "energy-saving mode".
- airspace element includes at least one of the following: logical antenna port, transmitting and receiving unit (TXRU), transmitting chain (Tx chain), or array antenna factor, etc.; in some implementations , "Airspace element” can also be directly replaced with "Power saving mode”; “Confirm to turn on or off at least part of the airspace element” can also be replaced with “Confirm to turn on or off energy saving mode”; or “Confirm to turn on or off “Turn off at least part of the airspace elements” can also be replaced by "Determine to activate or deactivate the energy saving mode".
- TXRU transmitting and receiving unit
- Tx chain transmitting chain
- array antenna factor etc.
- energy saving can be achieved through cell ON/OFF or reducing public signal transmission.
- the network is changed from "normal mode” to "energy-saving mode” by shutting down some cells.
- energy saving can be achieved through partial bandwidth part (BWP) switching and other methods. For example, by configuring a specific bandwidth part (BWP) for "normal mode” or "energy saving mode".
- BWP bandwidth part
- the network device also sends configuration information to the terminal device, wherein the configuration information configures a first timer related to one of the at least one energy saving mode; wherein the first timer sets The action time of one of the at least one energy-saving mode.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the action time of the energy-saving mode through a first timer, for example, 300 ms.
- high-layer signaling such as RRC signaling
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, from normal mode to energy-saving mode) and sends instruction information to the terminal device, the terminal device updates the CSI measurement method, and /or, CSI report update, and/or CSI-RS resource update, and/or BWP switching, and return to normal mode after 300ms. This will be explained separately in conjunction with the specific content indicated by the indication information later.
- the network device sends the indication information through semi-static signaling or dynamic signaling.
- the dynamic energy saving mode can be at the symbol or slot level. (less than milliseconds); for another example, under normal circumstances, a user's CSI-RS resources and CSI measurements do not need to change frequently, but during energy-saving operation, the normal mode and energy-saving mode will switch frequently. If the RRC signaling process is used It will bring a lot of overhead and cause a waste of system resources. Therefore, the above-mentioned embodiments of the present application can further reduce the signaling delay and overhead by sending the indication information through semi-static signaling or dynamic signaling, and can support switching of the dynamic energy-saving mode.
- the semi-static signaling may be MAC CE signaling; the dynamic signaling may be downlink control information (DCI).
- DCI downlink control information
- the dynamic signaling is DCI
- the indication information is carried through the DCI.
- the DCI can be a new DCI format (DCI format) in the energy-saving mode, or the existing DCI format can be reused. This application does not limit this, for example , when a new DCI format (DCI format) is introduced, the DCI format can be added by introducing a new wireless network temporary identifier (Radio Network Temporary Identity, RNTI), such as ES-RNTI (energy saving-RNTI). interference, specific time-frequency resources can also be allocated for the new DCI format so that the terminal device can recognize the DCI, and this application does not limit this.
- RNTI Radio Network Temporary Identity
- the indication information can be sent to the terminal device through signaling indicating changing the service mode; for example, the terminal device is instructed to activate/deactivate the "energy saving mode" through DCI, and the DCI can be carried along with the information. Indication information; optionally, the indication information can also be sent separately from the signaling indicating changing the service mode, and this application does not limit this.
- the semi-static signaling or the dynamic signaling is group signaling, and the network device sends indication information to multiple terminal devices through the group signaling; or, the semi-static signaling or the dynamic signaling
- the signaling is terminal equipment specific (UE specific) signaling, and the network device sends instruction information to a terminal equipment through the user equipment specific signaling.
- the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/or BWP switching.
- the instructions of the above instruction information will be schematically described below.
- the "CSI measurement method” means that the terminal device performs “merging processing” or “non-merging processing” on the CSI measurement results; for example, “merging processing” can also be replaced by “merging average” or “smoothing filtering”; where, “merging” For specific implementation methods of “processing” or “smoothing filtering”, please refer to the existing technology, and this application does not limit this.
- the terminal equipment in “normal mode" ("non-energy-saving mode"), the terminal equipment usually combines all CSI measurement results; however, when the "energy-saving mode” is turned on, the channel status indication reference signal (CSI-RS ) will change, and the latest CSI measurement method after the change from "normal mode” to "energy-saving mode” should also change accordingly to reflect the channel quality status in real time.
- CSI-RS channel status indication reference signal
- the CSI measurement results of "normal mode” and “energy-saving mode” may be merged, thus resulting in merging.
- the final CSI measurement results cannot truly reflect the channel status in energy-saving mode.
- the embodiment of the present application can use the indication information to enable the terminal device to promptly obtain whether the CSI measurement method is changed or not, thereby enabling more accurate CSI measurement.
- the network device indicates whether to change or not to change the CSI measurement method through indication information indicating that the CSI measurement method is updated and/or a first timer.
- the indication information when the network device changes the service mode, indicates changing the CSI measurement method through one value of one or more bits, and/or, through another value of the one or more bits. A value indicates that the CSI measurement method is not to be changed.
- the indication information is a bitmap including multiple blocks.
- each block corresponds to a terminal device, and the starting position and/or size of each block is configured by high-level signaling.
- Figure 3 is an example diagram of instruction information according to an embodiment of the present application.
- each block represents indication information of a terminal device, and the starting position and/or size of each block is given by high-level parameters.
- high-level parameters in existing standards can be used, or they can be introduced. New high-level parameters are not limited by this application.
- the network device can use 1 bit to indicate whether the CSI measurement method of the specific terminal device is to be changed or not. For example, if the bit is "1", to change the CSI measurement method, it can also be said , the CSI measurement merging process is not performed; this bit is "0", which means that the CSI measurement method is not changed, which can also be said that the CSI measurement merging process is performed.
- the specific content of the indication information is "11010", which means: for the first, second, and fourth terminal devices, CSI measurement merging processing is not performed; for the third and fourth terminal devices, Five terminal devices perform CSI measurement merging processing.
- the third terminal device obtains a total of 5 bits of indication information through high-level signaling, in which the size of each block is 1 bit, so the third terminal device can determine the third bit (with a value of "0") is the indication bit of the third terminal device.
- the indication information carries the block corresponding to the terminal device; if the CSI measurement method of the terminal device does not change, the indication information does not carry the block corresponding to the terminal device. For example, if the terminal device does not read the relevant fields of the indication information through high-layer signaling, it is considered that the CSI measurement method has not been changed, and the original CSI measurement method is still used.
- the network device can use 1 bit to indicate whether to change the CSI measurement method. For example, if the bit is "1", it means that the CSI measurement method is changed, which can also be said to not perform CSI measurement merging processing; if the bit is "0" ”, in order not to change the CSI measurement method, it can also be said that the CSI measurement merging process is performed.
- the terminal device changes the CSI measurement method after the first timer times out.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the activation time of the energy-saving mode.
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, enters the energy-saving mode from the normal mode) and sends instruction information to the terminal device (using the above instruction method), and the terminal device Update the CSI measurement method.
- the CSI measurement method will not be merged when the normal mode is changed to the energy-saving mode, and the normal mode will be restored after 300ms. Also, the CSI measurement method will be changed. For example, the CSI measurement when 300ms expires will not be merged.
- the terminal device can obtain the specific content of the indication information and perform CSI measurements more accurately.
- the network device activates/deactivates at least one CSI report through indication information indicating CSI report update and/or a first timer.
- the indication information indicates activating the first CSI reporting and/or deactivating the second CSI reporting, wherein the first CSI reporting and/or the second CSI reporting is performed by High-level information configuration.
- the first CSI report and/or the second CSI report belongs to a first CSI report list
- the first CSI report list includes a CSI report configuration index (CSI-ReportConfigId), where the first CSI report
- the list and the CSI report configuration index (CSI-ReportConfigId) are configured by higher layer information.
- each CSI report corresponds to a CSI report configuration index (CSI-ReportConfigId).
- CSI-ReportConfigId CSI report configuration index
- the high-level signaling configures the first CSI reporting list to include 5 CSI reports, corresponding to "CSI 0"-"CSI 4" respectively; the terminal The device determines which specific CSI report to activate/deactivate based on the instruction information.
- the CSI report configuration index (CSI-ReportConfigId) included in the first CSI report list is associated with changes in at least one of the following information:
- CSI reporting period and offset for example, indicated through the following fields of higher layer signaling: "CSI-ReportPeriodicityAndOffset", “reportSlotConfig” and “reportSlotOffsetList”;
- the resources used for CSI reporting are indicated by the following fields in higher layer signaling: "pucch-CSI-ResourceList";
- CSI reports the period and offset of the bound CSI-RS Resource, such as indicating "ResourceConfig" through the following fields of higher layer signaling; or CSI-
- the time-frequency resource of the bound CSI-RS Resource is reported by the CSI, for example, indicated by "CSI-ResourceConfig" in the following field of high-layer signaling.
- the CSI reporting period in energy-saving mode can be longer.
- the CSI reporting period in normal mode is 40ms
- the CSI reporting period in energy-saving mode is 80m.
- the upper layer configures the period of CSI 0 to be 80ms
- the cycle is 40ms
- the first CSI reporting list includes CSI 0 and CSI 1.
- the indication information can indicate activation of CSI 0 (first CSI reporting) and deactivation of CSI 1 (second CSI reporting). ), the following content of the description will further illustrate the implementation with examples.
- the CSI-RS resource bound to CSI reporting in energy-saving mode is CSI-RS 16port
- the CSI-RS resource bound to CSI reporting in normal mode is CSI-RS 32port.
- the upper layer configures CSI-RS 0 binding.
- CSI-RS 0 of 32port is bound
- CSI 1 is bound to CSI-RS 1 of 16port
- the first CSI report list includes CSI 0 and CSI 1.
- the indication information can indicate the activation of CSI 1 (section 1).
- Activating CSI 1 also means activating the CSI-RS 1 of its bound 16port.
- Deactivating CSI 0 also means deactivating its bound 32port.
- the indication information indicates activating the CSI report through one value of one or more bits, and indicates deactivating the CSI report through another value of the one or more bits.
- the indication information is a bitmap including multiple blocks; where each block corresponds to a terminal device, and the starting point of each block The starting position and/or size is configured by high-level signaling.
- Each block includes one or more bits.
- Each block indicates the first CSI report list of the terminal device.
- Each bit in each block corresponds to the first CSI report. Report the CSI in the list.
- each block (block) represents the indication information of a terminal device, and the starting position and/or size of each block (block) is given by high-level parameters. It is noted that, for example, high-level parameters in existing standards can be used, or new high-level parameters can be introduced, and this application does not limit this.
- each block corresponds to a first CSI report list of a specific terminal device, and each block includes, for example, X bits, where each bit of the X bits corresponds to a CSI report in the first CSI report list.
- Activation/deactivation status the list can be given by high-level parameters.
- the high-level parameters configure the first CSI report list to contain 5 CSI reports, corresponding to "CSI 0"-"CSI 4", and the activation/deactivation of each CSI report is indicated by 5 bits.
- Activation status for example, "0" represents deactivating CSI reporting, "1” represents activating CSI reporting; for example, the high-level parameters configure the CSI period of "CSI 0" (the first CSI reporting) to be 80m, "CSI 1"-”
- the CSI period of "CSI 4" (second CSI report) is 40m, and "10000" can be sent to the user equipment, which means to activate "CSI 0" and deactivate "CSI 1"-”CSI 4".
- the indication information is "'10000''10100''00011''00100''10001'"; taking the second terminal device as an example, the second terminal device obtains the The indication information is 25 bits in total, the starting position is bit 6, and the size of the indication information for this terminal is 5 bits, that is, the sixth to tenth bits are the indication bits of the second terminal device; among them, '10100' indicates
- activate CSI 0" (the first CSI report) and "CSI 2" (the first CSI report), and deactivate "CSI 1" (the second CSI report) and "CSI 3" (the second CSI report).
- the first CSI reporting list may be different for different terminal devices.
- the indication information carries the block corresponding to the terminal device; if the CSI reporting activation/deactivation status of the terminal device does not need to be updated, the indication information does not Carry the block corresponding to the terminal device. For example, if the terminal device does not read the relevant fields of the indication information through high-layer signaling, it is considered that the CSI reporting activation/deactivation status does not need to be updated.
- the first CSI reporting and/or the second CSI reporting includes: periodic CSI reporting, semi-persistent CSI reporting, or aperiodic CSI reporting; for example, periodic CSI reporting, semi-persistent CSI reporting, etc.
- periodic CSI reporting for example, periodic CSI reporting, semi-persistent CSI reporting, etc.
- aperiodic CSI reporting can be found in the prior art, and this application does not limit this.
- Figure 4 is an example diagram of CSI reporting according to an embodiment of the present application.
- the terminal device when the terminal device is in normal mode, its configured CSI report is "CSI 0", and its bound CSI-RS resource is “CSI-RS 0"; when the terminal device is in In the case of energy-saving mode, the configured CSI report is "CSI 1", and its bound CSI-RS resource is "CSI-RS 1"; for example, combined with the above method of updating CSI reporting, changing the service mode and entering the energy-saving mode
- the indication information sent by the network device is "...'01000'", and the corresponding updated activated CSI is reported as “CSI 1"; for example, when the service mode is changed to the normal mode, the indication information sent is is "...'10000'.", and the corresponding updated activated CSI is reported as "CSI 0".
- the network device may indicate the first CSI reporting list through X bits; each bit in the Deactivate CSI reporting.
- the content of each block in the above embodiment is used as the specific content of the specific signaling of the terminal device and is then sent to the specific terminal device.
- the specific instruction method please refer to the above embodiment, and the description will not be repeated here.
- the terminal device when the service mode changes, starts the first timer and suspends the CSI report before the service mode change; and the terminal device resumes the CSI report before the service mode change after the first timer times out.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the activation time of the energy-saving mode.
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, enters the energy-saving mode from the normal mode) and sends instruction information to the terminal device (using the above instruction method), and the terminal device Updated the activation/deactivation CSI reporting and suspended the activation/deactivation CSI reporting in the normal mode, and restored the normal mode after 300ms, that is, the first timer expires, and restored the activation/deactivation CSI in the normal mode. Report.
- the terminal device can obtain the specific content of the indication information and determine the CSI report update.
- the network device activates/deactivates at least one CSI-RS resource through indication information indicating CSI-RS resource update and/or a first timer.
- the indication information indicates activation of the first CSI-RS resource and/or deactivation of the second CSI-RS resource, wherein the first CSI-RS resource and/or The two CSI-RS resources are configured by higher layer information; wherein the first CSI-RS resource and/or the second CSI-RS resource are the same or different.
- the first CSI-RS resource and/or the second CSI-RS resource belongs to a first CSI-RS resource set, wherein the first CSI-RS resource set includes CSI-RS resources (CSI-RS resources). RS resource), and/or, CSI-RS port (CSI-RS port); wherein, the index of the first CSI-RS resource set and the CSI-RS resource (CSI-RS resource) included in the first CSI-RS resource set resource), and/or, the number and/or index of the CSI-RS port (CSI-RS port) are configured by high-layer information.
- high-level signaling configures the first CSI-RS resource set and its index
- the first CSI-RS resource set includes multiple CSI-RS resources, multiple CSI-RS ports, and related configurations, where multiple Related configurations of a CSI-RS resource and multiple CSI-RS ports can be found in the existing technology, and this application does not limit this.
- the first CSI-RS resource and/or the second CSI-RS resource belongs to the first CSI-RS resource set, where the first CSI-RS resource set includes CSI-RS resource (CSI-RS resource) as example.
- the indication information indicates the activation of the CSI-RS resource (CSI-RS resource) through a value of one or more bits, and the indication information uses a value of one or more bits. Or another value of multiple bits indicates deactivation of CSI-RS resource.
- the CSI-RS resource includes a group of CSI-RS resources (CSI-RS resource) or one CSI-RS resource (CSI-RS resource).
- the group of CSI-RS resources is configured by higher layer signaling.
- the indication information is a bitmap including multiple blocks; each block corresponds to a terminal device, and the start of each block The position and/or size are configured by high-level signaling; each bit corresponds to a set of CSI-RS resources (CSI-RS resource) or a CSI-RS resource (CSI-RS resource) of the terminal device, and the number of the bits is determined by High-level signaling configuration.
- each block (block) represents the indication information of a terminal device, and the starting position and/or size of each block (block) is given by high-level parameters. It is noted that, for example, high-level parameters in existing standards can be used, or new high-level parameters can be introduced, and this application does not limit this.
- each block corresponds to the activation/deactivation status of each CSI-RS resource in a CSI-RS resource set of a specific terminal device, for example,
- Each block includes X bits, where each of the X bits corresponds to the activation/deactivation status of the CSI-RS resource.
- the specific settings of the CSI-RS resource set (CSI-RS resource set) and its corresponding CSI-RS resource (CSI-RS resource) can be found in the prior art, and this application does not limit this.
- the first CSI-RS resource set includes 4 CSI-RS resources (CSI-RS resource), and the activation of each CSI-RS resource (CSI-RS resource) is indicated by 4 bits.
- /Deactivation status for example, "0” means deactivating the CSI-RS resource (CSI-RS resource), "1” means activating the CSI-RS resource (CSI-RS resource); “1010” means activation” CSI-RS resource 0" (first CSI-RS resource), “CSI-RS resource 2" (first CSI-RS resource), deactivate “CSI-RS resource 1" (second CSI-RS resource), " CSI-RS resource 3” (second CSI-RS resource).
- the indication information is "'1010''0101'"; taking the first terminal device as an example, the first terminal device obtains the indication information through high-level signaling, which is a total of 8-bit starting position. is the 1st bit and lasts for 4 bits, that is, the first to fourth bits are the indication bits for the first terminal device; among them, '1010' indicates that for the first terminal device, activate "CSI-RS resource 0" ", “CSI-RS Resource 2”, deactivate "CSI-RS Resource 1", “CSI-RS Resource 3".
- the indication information can also indicate the activation/deactivation status of a group of CSI-RS resources (CSI-RS resources).
- CSI-RS resources For example, "CSI-RS resource 0" and “CSI-RS resource 2" are group 0 ( Group 0); “CSI-RS resource 1” and “CSI-RS resource 3" are group 1 (Group 1); for two terminal devices, the indication information is "'10''01'”; with the first terminal Taking the device as an example, the first terminal device obtains the indication information through high-level signaling, which is 4 bits in total, in which the size of each block is 2 bits and "CSI-RS resource 0" and “CSI-RS resource 2" are Group 0 (Group 0), “CSI-RS Resource 1” and “CSI-RS Resource 3” are Group 1 (Group 1), and the first to second bits are the indication bits of the first terminal device; where, '10' indicates that for the first terminal device, activate “CSI-RS resource 0" and “CSI-RS resource 2", and deactivate "CSI-RS resource
- the indication information carries the block corresponding to the terminal device; if the CSI-RS resource (CSI-RS resource) of the terminal device needs to be updated, The activation/deactivation status of -RS resource) does not need to be updated, and the indication information does not carry the corresponding block of the terminal device. For example, if the terminal device does not read the relevant fields of the indication information through high-level signaling, it is considered that the activation/deactivation status of the CSI-RS resource does not need to be updated.
- Figure 5 is an example diagram of CSI-RS resource update according to this embodiment of the present application.
- 32-port CSI-RS can be supported through CDM-4 and 4 resources.
- one resource of CDM-4 occupies 8 resource elements. , RE), CDM-4 can refer to the existing technology, and this application does not limit this.
- a specific terminal device uses 32-port CSI-RS.
- the terminal device uses 16-port CSI-RS.
- the CSI-RS resources of the terminal device Change from activating "Resource 1 (Resource 1) - Resource 4 (Resource 4)" in Figure 5 to activating "Resource 1 (Resource 1), Resource 3 (Resource 3)", and deactivating "Resource 2 (Resource 2), Resource 4(Resource4)".
- the update of 32port CSI-RS resources to 16port CSI-RS resources can be realized; for example, the above instructions are used, and no repeated explanation will be made here.
- the network device can use X bits to indicate the activation/deactivation status of the CSI-RS resources (CSI-RS resource) included in a CSI-RS resource set; each bit in the Indicates the activation/deactivation status of the specific CSI-RS resource (CSI-RS resource).
- the network device can use X bits to indicate the activation/deactivation status of multiple sets of CSI-RS resources (CSI-RS resource) included in a CSI-RS resource set (CSI-RS resource set) .
- the content of each block in the above embodiment is used as the specific content of the specific signaling of the terminal device and is then sent to the specific terminal device.
- the specific instruction method please refer to the above embodiment, and the description will not be repeated here.
- the terminal device suspends the CSI-RS resources before the service mode change after the first timer times out; and the terminal device restores the CSI-RS resources before the service mode change after the first timer times out.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the activation time of the energy-saving mode.
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, enters the energy-saving mode from the normal mode) and sends instruction information to the terminal device (using the above instruction method), and the terminal device Update the activated/deactivated CSI-RS resources and suspend the activated/deactivated CSI-RS resources in the normal mode, and restore the normal mode after the 300ms first timer times out, and restore the activated/deactivated CSI in the normal mode -RS resources.
- the terminal device can obtain the specific content of the indication information and determine the updated activated/deactivated CSI-RS resource (CSI-RS resource).
- the first CSI-RS resource and/or the second CSI-RS resource belongs to a first CSI-RS resource set, where the first CSI-RS resource set includes a CSI-RS port (CSI-RS port): example.
- the indication information indicates deactivation of the CSI-RS port through one value of one or more bits, and indicates activation of the CSI-RS port through another value of the one or more bits.
- the CSI-RS port includes a group of CSI-RS ports or one CSI-RS port; the group of CSI-RS ports is configured by high-layer signaling.
- the indication information is a bitmap including multiple blocks; where each block corresponds to a terminal device, and the start of each block The position and/or size are configured by high-level signaling; each block includes one or more bits, each bit corresponds to a group of CSI-RS ports or one CSI-RS port of the terminal device, and the individual bits The number is configured by higher layer signaling.
- each block (block) represents the indication information of a terminal device, and the starting position and/or size of each block (block) is given by high-level parameters. It is noted that, for example, high-level parameters in existing standards can be used, or new high-level parameters can be introduced, and this application does not limit this.
- each block corresponds to the activation/deactivation status of a CSI-RS port of a specific terminal device.
- each block includes X bits, where each bit of the X bits corresponds to the CSI-RS port.
- RS port activation/deactivation status RS port activation/deactivation status.
- the specific settings of the CSI-RS port (port) can be referred to the existing technology, and this application does not limit this.
- each block example may also include CSI-RS resource related information, for example, including T bits (T may be equal to 0).
- T indicates the CSI corresponding to the CSI-RS port (port).
- T 0, that is, the CSI-RS resource set (CSI-RS resource set) and/or CSI-RS resource (CSI-RS resource) corresponding to the CSI-RS port (port) is not indicated as an example.
- a terminal device can be configured with 32 CSI-RS ports, and 32 bits are used to indicate the activation/deactivation status of the CSI-RS port. For example, “0” represents deactivating the CSI-RS port, and “1” represents activating the CSI-RS port.
- CSI-RS port; "00000000000000001111111111111” means activating "CSI-RS port 16" - "CSI-RS port 31", deactivating "CSI-RS port 0" - "CSI-RS port 15"; optional,
- the indication information can also indicate the activation/deactivation status of a group of CSI-RS ports.
- This group of CSI-RS ports can be one or more CDM groups, for example, "CSI-RS port 0" - "CSI-RS port 15" is Group 0 (Group 0); “CSI-RS port 16"-"CSI-RS port 31” is Group 1 (Group 1), or CSI-RS32 port has a total of 4 CDM groups, “CDM Group 0" and “CDM Group 1” is Group 0 (Group 0), “CDM Group 2" and “CDM Group 3" are Group 1 (Group 1).
- the indication information is "'10''01'"; taking the first terminal device as an example, the first terminal device obtains the indication information through high-level signaling, which is 4 bits in total.
- the starting position corresponding to the device is the 1st bit, a total of 2 bits and "CSI-RS port 0" - "CSI-RS port 15" are group 0 (Group0); "CSI-RS port 16" - “CSI-RS port 31” is Group 1 (Group 1), and the first to second bits are the indication bits of the first terminal device; among them, '10' indicates that for the first terminal device, activate “CSI-RS port 0 "-"CSI-RS port 15", deactivate "CSI-RS port 16"-"CSI-RS port 31".
- the instructions can be combined with the above-mentioned activation/deactivation of the CSI-RS port (port) and the above-mentioned activation/deactivation of the CSI-RS resource, which will not be repeated here in this application.
- the indication information carries the block corresponding to the terminal device; if the CSI-RS port of the terminal device does not need to be updated, the indication information does not Carry the block corresponding to the terminal device. For example, if the terminal device does not read the relevant fields of the indication information through high-layer signaling, it is considered that the activation/deactivation status of the CSI-RS port does not need to be updated.
- Figure 6 is an example diagram of CSI-RS port update according to an embodiment of the present application.
- 32-port CSI-RS can be supported through 4 CDM-8 and 1 resource.
- one resource of CDM-8 occupies 32 resource elements ( resource element, RE)
- CDM-8 can refer to the existing technology, and this application does not limit this.
- a specific terminal device uses 32-port CSI-RS.
- the terminal device uses 16-port CSI-RS.
- the CSI-RS resources of the terminal device From “activate CSI-RS ports 0-31" in Figure 6 to "activate CSI-RS ports 0-15", the update from 32port CSI-RS to 16port CSI-RS can be achieved; for example, using the above instructions The method will not be repeated here.
- the network device may indicate the CSI-RS port activation/deactivation status through X bits; each bit in the -RS port; "0" means deactivating the CSI-RS resource (CSI-RS resource); optionally, the network device can use X bits to indicate the activation/deactivation status of multiple groups of CSI-RS ports.
- the content of each block in the above embodiment is used as the specific content of the specific signaling of the terminal device and is then sent to the specific terminal device.
- the specific instruction method please refer to the above embodiment, and the description will not be repeated here.
- the terminal device suspends the CSI-RS port before the service mode change after the first timer times out; and the terminal device restores the CSI-RS port before the service mode change after the first timer times out.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the activation time of the energy-saving mode.
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, enters the energy-saving mode from the normal mode) and sends instruction information to the terminal device (using the above instruction method), and the terminal device Update the activated/deactivated CSI-RS port and suspend the activated/deactivated CSI-RS port in the normal mode, and restore the normal mode after the first timer timeout of 300ms, and restore the activated/deactivated CSI in the normal mode -RS port.
- high-layer signaling such as RRC signaling
- the terminal device can obtain the specific content of the indication information and determine the updated activated/deactivated CSI-RS port (CSI-RS port).
- the network device indicates the BWP after the service mode change through indication information indicating BWP switching and/or the first timer.
- the indication information indicates the BWP index after the service mode change; wherein the BWP index is configured by high-layer information.
- the BWP index is associated with a CSI report configuration index (CSI-ReportConfigId); wherein the CSI report configuration index (CSI-ReportConfigId) associated with the BWP index is configured by high-layer information.
- CSI-ReportConfigId CSI report configuration index
- switch when the network device changes the service mode, switch to activate the BWP corresponding to the BWP index after the service mode change, and at the same time activate the CSI report associated with the associated CSI report configuration index (CSI-ReportConfigId), and deactivate CSI report associated with the CSI report configuration index (CSI-ReportConfigId) associated with the BWP index before the service mode change.
- CSI-ReportConfigId CSI report configuration index
- the indication information is a bitmap including multiple blocks; each block corresponds to a terminal device, and the start of each block The position and/or size is configured by higher layer signaling; wherein each block includes one or more bits indicating the index of the BWP to be switched by the terminal device.
- each block (block) represents the indication information of a terminal device, and the starting position and/or size of each block (block) is given by high-level parameters. It is noted that, for example, high-level parameters in existing standards can be used, or new high-level parameters can be introduced, and this application does not limit this.
- each block corresponds to the index of the BWP that the terminal device is about to switch when at least part of the airspace elements are turned on or off.
- each block includes X bits, which correspond to the index of a BWP.
- the setting of BWP and its index can refer to the existing technology, and this application does not limit this.
- a terminal device is configured with 4 BWPs, and the indication information indicates the switching BWP index through 2 bits. For example, "00" represents switching to BWP 0, "01” represents switching to BWP 1, and “10” represents switching to BWP 2, "11” means switching to BWP 3.
- high-level signaling configures BWP 0 to associate with CSI 0, and BWP 1 to associate with CSI1.
- the service mode is changed to energy-saving mode, for example, if the indication information indicates "00", CSI 0 is correspondingly activated and the normal mode of the terminal device is deactivated.
- CSI reporting under normal mode for example, deactivating CSI 1 in normal mode configured by higher layer signaling.
- the indication information is "'10''01'"; taking the first terminal device as an example, the first terminal device obtains the indication through high-level signaling
- the information is 4 bits in total, where the size of each block is 2 bits, and the first to second bits are the indication bits for the first terminal device; among them, '10' indicates that for the first terminal device, Switch to BWP 2.
- the indication information if the BWP of the terminal device needs to be switched, the indication information carries the block corresponding to the terminal device; if the BWP of the terminal device does not need to be switched, the indication information does not carry the block corresponding to the terminal device. For example, if the terminal device does not read the relevant fields of the indication information through high-level signaling, it is considered that the BWP of the terminal device does not need to be switched.
- the terminal device suspends the BWP index before the service mode change; and the terminal device restores the BWP index before the service mode change after the first timer times out.
- the network device sends the configuration information through high-layer signaling, such as RRC signaling, where the configuration information indicates the activation time of the energy-saving mode.
- the terminal device obtains the action time of the energy-saving mode after reading the RRC signaling, the network device changes the service mode (for example, enters the energy-saving mode from the normal mode) and sends instruction information to the terminal device (using the above instruction method), and the terminal device Switch the BWP index and suspend the BWP index in normal mode, and restore the normal mode after the 300ms first timer times out, switch back to the BWP index in normal mode.
- the terminal device can obtain the specific content of the instruction information and determine the BWP index for handover.
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/ Or, BWP switch.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- the embodiment of the present application provides an information receiving method, which will be described from the terminal device side, and the overlapping parts with the embodiment of the first aspect will not be described again.
- Figure 7 is a schematic diagram of an information receiving method according to an embodiment of the present application. As shown in Figure 7, the method includes:
- the terminal device receives the instruction information
- the terminal device determines according to the indication information: the channel state information (CSI) measurement method is updated; and/or the channel state information (CSI) report is updated; and/or the channel state information reference signal (CSI-RS) resource is updated. ; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference signal
- the service mode includes a normal mode and/or at least one energy saving mode.
- the terminal device further receives configuration information, wherein the configuration information configures a first timer related to one of the at least one energy saving mode; wherein the first timer sets the at least one energy saving mode. The action time of one of the energy-saving modes.
- the terminal device receives the indication information through semi-static signaling or dynamic signaling; wherein,
- the semi-static signaling or the dynamic signaling is group signaling, and the network device sends the instruction information to multiple terminal devices through the group signaling; or the semi-static signaling or the dynamic signaling is user equipment-specific signaling. , the network device sends the indication information to a terminal device through the user equipment specific signaling.
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/ Or, BWP switch.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- An embodiment of the present application provides an information indication device.
- the device may be, for example, a network device, or may be some or some components or components configured on the network device. The same content as the embodiment of the first aspect will not be described again.
- FIG 8 is a schematic diagram of the information indicating device 800 in the embodiment of the present application. As shown in Figure 8, the information indicating device 800 includes:
- the sending unit 802 sends indication information to the terminal device, where the indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- indication information indicates: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference Signal (CSI-RS) resource update; and/or, partial bandwidth (BWP) switching.
- CSI channel state information
- CSI channel state information
- CSI-RS channel state information reference Signal
- the service mode includes a normal mode and/or at least one energy saving mode.
- the sending unit 802 also sends configuration information to the terminal device, wherein the configuration information configures a first timer related to one of the at least one energy saving mode; wherein the first timer Set the action time of one of the at least one energy-saving mode.
- the sending unit 802 sends the indication information through semi-static signaling or dynamic signaling; where the semi-static signaling or dynamic signaling is group signaling, and the network device sends signals to multiple terminal devices through the group signaling.
- the indication information is sent; or the semi-static signaling or dynamic signaling is user equipment specific signaling, and the network device sends the indication information to a terminal device through the user equipment specific signaling.
- the network device indicates whether to change or not to change the CSI measurement method through indication information indicating that the CSI measurement method is updated and/or a first timer.
- the indication information indicating the update of the CSI measurement method indicates changing the CSI measurement method through a value of one or more bits, and/or, through the one or Another value of multiple bits indicates that the CSI measurement method is not changed.
- the terminal device changes the CSI measurement method after the first timer times out.
- the network device activates/deactivates at least one CSI report through indication information indicating CSI report update and/or a first timer.
- the indication information indicating the CSI reporting update indicates activating the first CSI reporting and/or deactivating the second CSI reporting, wherein the first CSI reporting and/or The second CSI report is configured by higher layer information.
- the terminal device suspends the CSI report before the service mode change; and the terminal device resumes the CSI report before the service mode change after the first timer times out.
- the first CSI report and/or the second CSI report belongs to a first CSI report list
- the first CSI report list includes a CSI report configuration index (CSI-ReportConfigId), where the first CSI report
- the list and the CSI report configuration index (CSI-ReportConfigId) are configured by higher layer information.
- the first CSI reporting and/or the second CSI reporting includes: periodic CSI reporting, semi-persistent CSI reporting, or aperiodic CSI reporting.
- the CSI report configuration index (CSI-ReportConfigId) included in the first CSI report list is associated with changes in at least one of the following information: CSI reporting period and offset (offset); resources used for CSI reporting; CSI reporting Report the period and offset of the bound CSI-RS Resource; or CSI reports the time-frequency resource of the bound CSI-RS Resource.
- the network device activates/deactivates at least one CSI-RS resource through the indication information indicating CSI-RS resource update and/or the first timer.
- the indication information indicating CSI-RS resource update indicates activation of the first CSI-RS resource and/or deactivation of the second CSI-RS resource, wherein, the The first CSI-RS resource and/or the second CSI-RS resource are configured by higher layer information; wherein the first CSI-RS resource and/or the second CSI-RS resource are the same or different.
- the terminal device suspends the CSI-RS resources before the service mode change; and the terminal device restores the CSI-RS resources before the service mode change after the first timer times out.
- the first CSI-RS resource and/or the second CSI-RS resource belong to a first CSI-RS resource set, wherein the first CSI-RS resource set includes CSI-RS resources (CSI-RS resource ), and/or, CSI-RS port; wherein, the index of the first CSI-RS resource set and the CSI-RS resource (CSI-RS resource) included in the first CSI-RS resource set
- the number and index, and/or, the number and/or index of the CSI-RS port (CSI-RS port) are configured by high-layer information.
- the network device indicates the BWP after the service mode change through the indication information indicating BWP switching and/or the first timer.
- the indication information indicating BWP switching indicates the BWP index after the service mode change; wherein the BWP index is configured by high-layer information.
- the terminal device also suspends the BWP index before the service mode change; and the terminal device restores the BWP index before the service mode change after the first timer times out.
- the BWP index is associated with a CSI report configuration index (CSI-ReportConfigId); wherein the CSI report configuration index (CSI-ReportConfigId) associated with the BWP index is configured by high-layer information.
- CSI-ReportConfigId CSI report configuration index
- the network device when the network device changes the service mode, it switches to activate the BWP corresponding to the partial bandwidth (BWP) index after the service mode change, and simultaneously activates the associated channel state information reporting configuration index (CSI-ReportConfigId ), deactivate the channel state information (CSI) reporting associated with the partial bandwidth (BWP) index before the service mode change.
- the indication information is a bitmap including multiple blocks; each block corresponds to a terminal device, and the starting point of each block The starting position and/or size is configured by higher layer signaling.
- the information indication device 800 may also include other components or modules.
- the specific content of these components or modules please refer to related technologies.
- FIG. 8 only illustrates the connection relationships or signal directions between various components or modules, but those skilled in the art should know that various related technologies such as bus connections can be used.
- Each of the above components or modules can be implemented by hardware facilities such as a processor, a memory, a transmitter, a receiver, etc.; the implementation of this application is not limited to this.
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/ Or, BWP switch.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- An embodiment of the present application provides an information receiving device.
- the device may be, for example, a terminal device, or may be some or some components or components configured in the terminal device, and the same content as the embodiment of the second aspect will not be described again.
- Figure 9 is an example diagram of the information receiving device 900 in the embodiment of the present application. As shown in Figure 9, the information receiving device 900 includes:
- Receiving unit 901 which receives indication information
- the determining unit 902 determines according to the indication information: channel state information (CSI) measurement mode update; and/or channel state information (CSI) reporting update; and/or channel state information reference signal (CSI-RS) resources Update; and/or, Bandwidth Partial (BWP) switching.
- CSI channel state information
- CSI-RS channel state information reference signal
- the service mode includes a normal mode and/or at least one energy saving mode.
- the receiving unit 901 also receives configuration information, wherein the configuration information configures a first timer related to one of the at least one energy saving mode; wherein the first timer sets the Describes the action time of one of the at least one energy-saving mode.
- the receiving unit 901 receives the indication information through semi-static signaling or dynamic signaling; wherein the semi-static signaling or the dynamic signaling is group signaling, and the network device sends messages to multiple groups through the group signaling.
- the terminal device sends the indication information; or, the semi-static signaling or dynamic signaling is user equipment specific signaling, and the network device sends the indication information to a terminal device through user equipment specific signaling.
- the information receiving device 900 may also include other components or modules.
- the specific contents of these components or modules please refer to related technologies.
- FIG. 9 only illustrates the connection relationships or signal directions between various components or modules, but it should be clear to those skilled in the art that various related technologies such as bus connections can be used.
- Each of the above components or modules can be implemented by hardware facilities such as a processor, a memory, a transmitter, a receiver, etc.; the implementation of this application is not limited to this.
- the network device changes the service mode and sends indication information to the terminal device, where the indication information indicates: CSI measurement mode update; and/or CSI reporting update; and/or CSI-RS resource update; and/ Or, BWP switch.
- the terminal device can adapt to the changed service mode without ambiguity through the indication information, and accurately determine the CSI measurement method update and/or CSI reporting update and/or CSI-RS resource update and/or BWP handover and other information, making it more efficient. to perform subsequent transmission of uplink data or reception of downlink data with network equipment.
- An embodiment of the present application also provides a communication system. Refer to FIG. 1 , and the same content as the embodiments of the first to fourth aspects will not be described again.
- the communication system 100 may include at least: a terminal device 102 and/or a network device 101.
- the implementation of the terminal device 102 may refer to the following network device 1000, and the implementation of the network device 101 may refer to the following terminal device 1100.
- the embodiment of the present application also provides a network device, which may be a base station, for example.
- a network device which may be a base station, for example.
- the present application is not limited thereto and may also be other network devices.
- FIG. 10 is a schematic diagram of the structure of a network device according to an embodiment of the present application.
- network device 1000 may include: a processor 1010 (eg, a central processing unit CPU) and a memory 1020 ; the memory 1020 is coupled to the processor 1010 .
- the memory 1020 can store various data; in addition, it also stores an information processing program 1030, and the program 1030 is executed under the control of the processor 1010.
- the processor 1010 may be configured to execute a program to implement the information indication method as described in the embodiment of the first aspect.
- the network device 1000 may also include: a transceiver 1040, an antenna 1050, etc.; the functions of the above components are similar to those of the existing technology and will not be described again here. It is worth noting that the network device 1000 does not necessarily include all components shown in Figure 10; in addition, the network device 1000 may also include components not shown in Figure 10, and reference can be made to the existing technology.
- the embodiment of the present application also provides a terminal device, but the present application is not limited to this and may also be other devices.
- Figure 11 is a schematic diagram of a terminal device according to an embodiment of the present application.
- the terminal device 1100 may include a processor 1110 and a memory 1120; the memory 1120 stores data and programs and is coupled to the processor 1110. It is worth noting that this figure is exemplary; other types of structures may also be used to supplement or replace this structure to implement telecommunications functions or other functions.
- the processor 1110 may be configured to execute a program to implement the information receiving method described in the embodiment of the second aspect.
- the terminal device 1100 may also include: a communication module 1130, an input unit 1140, a display 1150, and a power supply 1160.
- the functions of the above components are similar to those in the prior art and will not be described again here. It is worth noting that the terminal device 1100 does not necessarily include all the components shown in FIG. 11 , and the above components are not required; in addition, the terminal device 1100 may also include components not shown in FIG. 11 , please refer to the current There is technology.
- An embodiment of the present application also provides a computer program, wherein when the program is executed in a network device, the program causes the terminal device to execute the information indication method described in the embodiment of the first aspect.
- An embodiment of the present application also provides a storage medium storing a computer program, wherein the computer program causes the network device to execute the information indication method described in the embodiment of the first aspect.
- An embodiment of the present application also provides a computer program, wherein when the program is executed in a terminal device, the program causes the terminal device to execute the information receiving method described in the embodiment of the second aspect.
- An embodiment of the present application also provides a storage medium storing a computer program, wherein the computer program causes the terminal device to execute the information receiving method described in the embodiment of the second aspect.
- the above devices and methods of this application can be implemented by hardware, or can be implemented by hardware combined with software.
- the present application relates to a computer-readable program that, when executed by a logic component, enables the logic component to implement the apparatus or component described above, or enables the logic component to implement the various methods described above or steps.
- This application also relates to storage media used to store the above programs, such as hard disks, magnetic disks, optical disks, DVDs, flash memories, etc.
- the methods/devices described in connection with the embodiments of the present application may be directly embodied as hardware, a software module executed by a processor, or a combination of both.
- one or more of the functional block diagrams and/or one or more combinations of the functional block diagrams shown in the figure may correspond to each software module of the computer program flow, or may correspond to each hardware module.
- These software modules can respectively correspond to the various steps shown in the figure.
- These hardware modules can be implemented by solidifying these software modules using a field programmable gate array (FPGA), for example.
- FPGA field programmable gate array
- the software module may be located in RAM memory, flash memory, ROM memory, EPROM memory, EEPROM memory, registers, hard disk, removable disk, CD-ROM, or any other form of storage medium known in the art.
- a storage medium may be coupled to the processor such that the processor can read information from the storage medium and write information to the storage medium; or the storage medium may be an integral part of the processor.
- the processor and storage media may be located in an ASIC.
- the software module can be stored in the memory of the mobile terminal or in a memory card that can be inserted into the mobile terminal.
- the software module can be stored in the MEGA-SIM card or the large-capacity flash memory device.
- One or more of the functional blocks and/or one or more combinations of the functional blocks described in the accompanying drawings may be implemented as a general-purpose processor or a digital signal processor (DSP) for performing the functions described in this application. ), application specific integrated circuit (ASIC), field programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic device, discrete hardware component, or any appropriate combination thereof.
- DSP digital signal processor
- ASIC application specific integrated circuit
- FPGA field programmable gate array
- One or more of the functional blocks and/or one or more combinations of the functional blocks described in the accompanying drawings can also be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, or multiple microprocessors. processor, one or more microprocessors combined with DSP communications, or any other such configuration.
- An information indication method, applied to network equipment, the information indication method includes:
- the network device changes the service mode
- the network device sends indication information to the terminal device, where the indication information indicates:
- the first timer sets the action time of one of the at least one energy-saving mode.
- the semi-static signaling or the dynamic signaling is group signaling, and the network device sends the indication information to multiple terminal devices through the group signaling; or
- the semi-static signaling or the dynamic signaling is user equipment specific signaling, and the network device sends the indication information to a terminal device through the user equipment specific signaling.
- the indication information indicating CSI reporting update indicates activating the first CSI reporting and/or deactivating the second CSI reporting, wherein the first CSI report and/or the second CSI report are configured by higher layer information.
- the terminal device resumes CSI reporting before the service mode change after the first timer times out.
- the first CSI report and/or the second CSI report belong to a first CSI report list
- the first CSI report list includes CSI reports Configuration index (CSI-ReportConfigId), wherein the first CSI reporting list and the CSI reporting configuration index (CSI-ReportConfigId) are configured by higher layer information.
- CSI-ReportConfigId CSI reports Configuration index
- first CSI reporting and/or the second CSI reporting includes: periodic CSI reporting, semi-persistent CSI reporting, or aperiodic Sexual CSI reporting.
- CSI report configuration index (CSI-ReportConfigId) included in the first CSI report list is associated with a change of at least one of the following information:
- CSI reports the time-frequency resources of the bound CSI-RS Resource.
- the indication information indicating CSI-RS resource update indicates activating the first CSI-RS resource and/or deactivating the service mode.
- Activate the second CSI-RS resource wherein the first CSI-RS resource and/or the second CSI-RS resource are configured by higher layer information; wherein the first CSI-RS resource and/or the second CSI-RS resource
- the CSI-RS resources are the same or different.
- the terminal device restores the CSI-RS resources before the service mode change after the first timer times out.
- the first CSI-RS resource set includes CSI-RS resources (CSI-RS resource) and/or CSI-RS port (CSI-RS port);
- the number and/or index of ports (CSI-RS port) are configured by high-level information.
- the indication information indicating BWP switching indicates the BWP index after the service mode change; wherein, the BWP indexes are configured by high-level information.
- the terminal device restores the BWP index before the service mode change after the first timer times out.
- the indication information is a bitmap including a plurality of blocks; wherein each A block corresponds to a terminal device, and the starting position and/or size of each block is configured by high-level signaling.
- An information receiving method, applied to terminal equipment, the information receiving method includes:
- the terminal device receives indication information
- the terminal device determines according to the indication information:
- the terminal device also receives configuration information, wherein the configuration information configures a first timer related to one of the at least one energy-saving mode;
- the first timer sets the action time of one of the at least one energy-saving mode.
- the semi-static signaling or dynamic signaling is group signaling, and the network device sends the indication information to multiple terminal devices through the group signaling; or,
- the semi-static signaling or dynamic signaling is user equipment specific signaling, and the network device sends the indication information to a terminal device through the user equipment specific signaling.
- a terminal device comprising a memory and a processor
- the memory stores a computer program
- the processor is configured to execute the computer program to implement the data scheduling method as described in any one of appendices 24 to 27 .
- a network device including a memory and a processor, the memory stores a computer program, the processor is configured to execute the computer program to implement the data sending method as described in any one of appendices 1 to 23 .
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Abstract
本申请实施例提供一种信息指示、信息接收装置以及方法。网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
Description
本申请实施例涉及通信技术领域。
网络节能对于环境的可持续性、减少对环境的影响(温室气体排放)以及节约运营成本都具有重要意义。随着第五代移动通信技术(5th Generation Mobile Communication Technology,5G)在各行各业和地理区域的普及,处理更先进的服务和应用需要非常高的数据速率,网络部署变得更加密集,使用了更多的天线,更大的带宽和更多的频带。5G对环境的影响需要得到控制,需要开发新的解决方案来提高网络节能。
能源消耗已成为运营商运营成本的重要组成部分。根据全球移动通信系统协会(GSMA)的报告,移动网络的能源成本约占运营商总成本的23%。大部分能源消耗来自于无线接入网络,特别是有源天线单元(AAU),数据中心和光纤传输占了较小的份额。无线接入的功耗可以分为两部分:动态部分仅在数据传输/接收进行时消耗,静态部分则一直消耗,以维持无线接入设备的必要操作,即使数据传输/接收不进行。
应该注意,上面对技术背景的介绍只是为了方便对本申请的技术方案进行清楚、完整的说明,并方便本领域技术人员的理解而阐述的。不能仅仅因为这些方案在本申请的背景技术部分进行了阐述而认为上述技术方案为本领域技术人员所公知。
发明内容
目前,由于大带宽/多天线/多通道等技术的引入,基站的耗能较大,已经成为全球运营商最迫切解决的问题之一。
当前Release 18(R18)阶段引入了网络节能的议题。网络节能技术可以分为时域/频域/空域/能量域等类型,但在实际应用中,更可能通过两种或以上类型的节能技术相结合使用。例如,在空域节能技术方面,可以通过调整空域元素来达到节能的目的。这里的空域元素包括逻辑天线端口,发送传输单元(transmitting and receiving unit,TXRU),发送链(Tx chain),阵列天线因子等;在时域节能技术方面,可以通过cell ON/OFF或减少公共信道/信号传输的方法来达到节能;在频域节能技术方面,可以通过部分带宽(bandwidth part,BWP)切换等方法实现节能。通过上述节能技术,网络设备进入节能模式(节电模式或睡眠模式)。网络设备在正常(普通)模式和节能模式之间变更时,会影响终端相关处理,包括信道状态信息(CSI)测量方式更新,信道状态信息(CSI)上报更新,信道状态信息参考信号(CSI-RS)资源更新,部分带宽(BWP)切换等。上述相关处理是网络设备调度终端设备进行数据接收和数据发送的基础。上述相关处理又涉及到网络设备对终端设备的配置、指示以及终端设备向网络设备上报。
如何使得网络设备和终端设备能够没有歧义的适应不同模式的影响是网络节能技术是否能够被应用在实际部署中的关键问题,亟待解决。
针对上述问题的至少之一,本申请实施例提供一种信息指示、信息接收装置以及方法。网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
根据本申请实施例的一个方面,提供一种信息指示装置,应用于网络设备,所述装置包括:
变更单元,其改变服务模式;
发送单元,其向终端设备发送指示信息,其中,所述指示信息指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
根据本申请实施例的另一个方面,提供一种信息接收装置,应用于终端设备,所述装置包括:
接收单元,其接收指示信息;
确定单元,其根据所述指示信息确定:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
根据本申请实施例的另一个方面,提供一种信息指示方法,应用于网络设备,所 述信息指示方法包括:
所述网络设备改变服务模式;以及
所述网络设备向终端设备发送指示信息,其中,所述指示信息指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
根据本申请实施例的另一个方面,提供种信息接收方法,应用于终端设备,所述信息接收方法包括:
所述终端设备接收指示信息;
所述终端设备根据所述指示信息确定:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
本申请实施例的有益效果之一在于:网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
参照后文的说明和附图,详细公开了本申请的特定实施方式,指明了本申请的原理可以被采用的方式。应该理解,本申请的实施方式在范围上并不因而受到限制。在所附权利要求的精神和条款的范围内,本申请的实施方式包括许多改变、修改和等同。
针对一种实施方式描述和/或示出的特征可以以相同或类似的方式在一个或更多个其它实施方式中使用,与其它实施方式中的特征相组合,或替代其它实施方式中的特征。
应该强调,术语“包括/包含”在本文使用时指特征、整件、步骤或组件的存在,但并不排除一个或更多个其它特征、整件、步骤或组件的存在或附加。
在本申请实施例的一个附图或一种实施方式中描述的元素和特征可以与一个或更多个其它附图或实施方式中示出的元素和特征相结合。此外,在附图中,类似的标 号表示几个附图中对应的部件,并可用于指示多于一种实施方式中使用的对应部件。
图1是本申请实施例的通信系统的示意图;
图2是本申请实施例的信息指示方法的一示意图;
图3为本申请实施例指示信息的一示例图;
图4是本申请实施例CSI上报的一示例图;
图5是本申请实施例CSI-RS resource更新的一示例图;
图6是本申请实施例CSI-RS端口更新的一示例图;
图7是本申请实施例的信息接收方法的一示意图;
图8是本申请实施例中信息指示装置的一示意图;
图9是本申请实施例中信息接收装置的一示意图;
图10是本申请实施例的网络设备的构成示意图;
图11是本申请实施例的终端设备的构成示意图。
参照附图,通过下面的说明书,本申请的前述以及其它特征将变得明显。在说明书和附图中,具体公开了本申请的特定实施方式,其表明了其中可以采用本申请的原则的部分实施方式,应了解的是,本申请不限于所描述的实施方式,相反,本申请包括落入所附权利要求的范围内的全部修改、变型以及等同物。
在本申请实施例中,术语“第一”、“第二”等用于对不同元素从称谓上进行区分,但并不表示这些元素的空间排列或时间顺序等,这些元素不应被这些术语所限制。术语“和/或”包括相关联列出的术语的一种或多个中的任何一个和所有组合。术语“包含”、“包括”、“具有”等是指所陈述的特征、元素、元件或组件的存在,但并不排除存在或添加一个或多个其它特征、元素、元件或组件。
在本申请实施例中,单数形式“一”、“该”等包括复数形式,应广义地理解为“一种”或“一类”而并不是限定为“一个”的含义;此外术语“所述”应理解为既包括单数形式也包括复数形式,除非上下文另外明确指出。此外术语“根据”应理解为“至少部分根据……”,术语“基于”应理解为“至少部分基于……”,除非上下文另外明确指出。
在本申请实施例中,术语“通信网络”或“无线通信网络”可以指符合如下任意通信标准的网络,例如长期演进(LTE)、增强的长期演进(LTE-A,LTE-Advanced)、宽 带码分多址接入(WCDMA,Wideband Code Division Multiple Access)、高速报文接入(HSPA,High-Speed Packet Access)等等。
并且,通信系统中设备之间的通信可以根据任意阶段的通信协议进行,例如可以包括但不限于如下通信协议:1G(generation)、2G、2.5G、2.75G、3G、4G、4.5G以及5G、新无线(NR,New Radio)等等,和/或其它目前已知或未来将被开发的通信协议。
在本申请实施例中,术语“网络设备”例如是指通信系统中将终端设备接入通信网络并为该终端设备提供服务的设备。网络设备可以包括但不限于如下设备:基站(BS,Base Station)、接入点(AP、Access Point)、发送接收点(TRP,Transmission Reception Point)、广播发射机、移动管理实体(MME、Mobile Management Entity)、网关、服务器、无线网络控制器(RNC,Radio Network Controller)、基站控制器(BSC,Base Station Controller)等等。
其中,基站可以包括但不限于:节点B(NodeB或NB)、演进节点B(eNodeB或eNB)以及5G基站(gNB),IAB宿主等等,此外还可包括远端无线头(RRH,Remote Radio Head)、远端无线单元(RRU,Remote Radio Unit)、中继(relay)或者低功率节点(例如femeto、pico等等)。并且术语“基站”可以包括它们的一些或所有功能,每个基站可以对特定的地理区域提供通信覆盖。术语“小区”可以指的是基站和/或其覆盖区域,这取决于使用该术语的上下文。
在本申请实施例中,术语“用户设备”(UE,User Equipment)或者“终端设备”(TE,Terminal Equipment或Terminal Device)例如是指通过网络设备接入通信网络并接收网络服务的设备。终端设备可以是固定的或移动的,并且也可以称为移动台(MS,Mobile Station)、终端、用户台(SS,Subscriber Station)、接入终端(AT,Access Terminal)、站,等等;例如,“用户设备”和“终端设备”也可以相互替换使用。
其中,终端设备可以包括但不限于如下设备:蜂窝电话(Cellular Phone)、个人数字助理(PDA,Personal Digital Assistant)、无线调制解调器、无线通信设备、手持设备、机器型通信设备、膝上型计算机、无绳电话、可穿戴设备、智能手机、智能手表、数字相机,等等。
再例如,在物联网(IoT,Internet of Things)等场景下,终端设备还可以是进行监控或测量的机器或装置,例如可以包括但不限于:机器类通信(MTC,Machine Type Communication)终端、车载通信终端、工业无线设备、监控摄像头、设备到设备(D2D,Device to Device)终端、机器到机器(M2M,Machine to Machine)终端,等等。
此外,术语“网络侧”或“网络设备侧”是指网络的一侧,可以是某一基站或某一核心网设备,也可以包括如上的一个或多个网络设备。术语“用户侧”或“终端侧”或“终端设备侧”是指用户或终端的一侧,可以是某一UE,也可以包括如上的一个或多个终端设备。本文在没有特别指出的情况下,“设备”可以指网络设备,也可以指终端设备。
在以下的说明中,在不引起混淆的情况下,术语“上行控制信号”和“上行控制信息(UCI,Uplink Control Information)”或“物理上行控制信道(PUCCH,Physical Uplink Control Channel)”可以互换,术语“上行数据信号”和“上行数据信息”或“物理上行共享信道(PUSCH,Physical Uplink Shared Channel)”可以互换,“小区”和“载波”和“服务小区”和“载波分量”可以互换。术语“下行控制信号”和“下行控制信息(DCI,Downlink Control Information)”或“物理下行控制信道(PDCCH,Physical Downlink Control Channel)”可以互换,术语“下行数据信号”和“下行数据信息”或“物理下行共享信道(PDSCH,Physical Downlink Shared Channel)”可以互换,DCI和DCI格式(format)可以互换。
另外,发送或接收PUSCH可以理解为发送或接收由PUSCH承载的上行数据,发送或接收PUCCH可以理解为发送或接收由PUCCH承载的上行信息(e.g.UCI),发送或接收PRACH可以理解为发送或接收由PRACH承载的preamble;发送或接收PDSCH可以理解为发送或接收由PDSCH承载的下行数据,发送或接收PDCCH可以理解为发送或接收由PDCCH承载的下行信息(e.g.DCI)。
在本申请实施例中,高层信令例如可以是无线资源控制(RRC)信令;RRC信令例如包括RRC消息(RRC message),例如包括主信息块(MIB)、系统信息(system information)、专用RRC消息;或者RRC信息元素(RRC information element,RRC IE);或者RRC消息或RRC信息元素包括的信息域(或信息域包括的信息域)。高层信令例如还可以是媒体接入控制层(Medium Access Control,MAC)信令;或者称为MAC控制元素(MAC control element,MAC CE)。但本申请不限于此。
以下通过示例对本申请实施例的场景进行说明,但本申请不限于此。
图1是本申请实施例的通信系统的示意图,示意性说明了以终端设备和网络设备为例的情况,如图1所示,通信系统100可以包括网络设备101和终端设备102、103。 为简单起见,图1仅以两个终端设备和一个网络设备为例进行说明,但本申请实施例不限于此。
在本申请实施例中,网络设备101和终端设备102、103之间可以进行现有的业务或者未来可实施的业务发送。例如,这些业务可以包括但不限于:增强的移动宽带(eMBB,enhanced Mobile Broadband)、大规模机器类型通信(mMTC,massive Machine Type Communication)、高可靠低时延通信(URLLC,Ultra-Reliable and Low-Latency Communication)和减少能力的终端设备的相关通信,等等。
值得注意的是,图1示出了两个终端设备102、103均处于网络设备101的覆盖范围内,但本申请不限于此。两个终端设备102、103可以均不在网络设备101的覆盖范围内,或者一个终端设备102在网络设备101的覆盖范围之内而另一个终端设备103在网络设备101的覆盖范围之外。
当前Release 18(R18)阶段引入了网络节能的议题。网络节能技术可以分为时域/频域/空域/能量域等类型,但在实际应用中,更可能通过两种或以上类型的节能技术相结合使用。例如,在空域节能技术方面,可以通过调整空域元素来达到节能的目的。这里的空域元素包括逻辑天线端口,发送传输单元(transmitting and receiving unit,TXRU),发送链(Tx chain),阵列天线因子等;在时域节能技术方面,可以通过cell ON/OFF或减少公共信号传输的方法来达到节能;在频域节能技术方面,可以通过部分带宽(bandwidth part,BWP)切换等方法实现节能。通过上述节能技术,网络设备进入节能模式(节电模式或睡眠模式)。网络设备在正常(普通)模式和节能模式之间变更时,会影响终端相关处理,包括信道状态信息(CSI)测量方式更新,信道状态信息(CSI)上报更新,信道状态信息参考信号(CSI-RS)资源更新,部分带宽(BWP)切换等。上述相关处理是网络设备调度终端设备进行数据接收和数据发送的基础。上述相关处理又涉及到网络设备对终端设备的配置、指示以及终端设备向网络设备上报。
以空域节能技术为例,可以通过调整空域元素数量来进行至少一种节能模式或者正常(普通)模式的改变,在通过调整空域元素数量达到节能的过程中终端设备可能改变CSI测量方式;此外,原则上,空域元素数量不能小于CSI-RS端口数量,否则CSI-RS不能正常配置;在通过调整空域元素数量达到节能的过程中,当节能模式开 启或关闭后,可能会造成空域元素数量小于CSI-RS端口数,进而需要更新CSI-RS时频空资源。
因此,如何使得网络设备和终端设备能够没有歧义的适应不同模式的影响是网络节能技术是否能够被应用在实际部署中的关键问题,亟待解决。针对上述问题的至少之一,本申请实施例提供一种信息指示、信息接收装置以及方法。
第一方面的实施例
本申请实施例提供一种信息指示方法,从网络设备侧进行说明。
图2是本申请实施例的信息指示方法的一示意图,如图2所示,该方法包括:
201,网络设备改变服务模式;
202,该网络设备向终端设备发送指示信息,其中,该指示信息指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
在一些实施方式中,服务模式包括正常模式和/或至少一种节能模式。
例如,“至少一种节能模式”可以包括以下模式的至少一种:“节能模式”,“轻节能模式”,“深节能模式”,或“节能过渡模式”等,本申请对此不进行限制;上述“正常模式”还可以替换为“普通模式”;上述“节能模式”还可以替换为“节电模式”或“睡眠模式”或“非节能模式”或“关闭模式”等表述,本申请对此不进行限制。
在一些实施方式中,可以通过变更“空域元素”或者变更“天线模式”等方式改变服务模式,例如,通过关闭一部分“空域元素”使得网络从“正常模式”变更为“节能模式”。
在一些实施方式中,“空域元素”包括以下至少之一:逻辑天线端口、发送传输单元(transmitting and receiving unit,TXRU)、发送链(Tx chain)、或阵列天线因子等;在一些实施方式中,“空域元素”也可以直接替换为“节能模式”(“Power saving mode”);“确定开启或关闭至少一部分空域元素”也可以替换为“确定开启或关闭节 能模式”;或者“确定开启或关闭至少一部分空域元素”也可以替换为“确定激活或去激活节能模式”。
在一些实施方式中,在时域节能技术方面,可以通过cell ON/OFF或减少公共信号传输的方法来达到节能。例如,通过关闭一部分小区使得网络从“正常模式”变更为“节能模式”。
在一些实施方式中,在频域节能技术方面,可以通过部分带宽(bandwidth part,BWP)切换等方法实现节能。例如,通过配置特定的部分带宽(bandwidth part,BWP)对“正常模式”或“节能模式”。
在一些实施方式中,网络设备还发送配置信息给终端设备,其中,该配置信息配置与至少一种节能模式中的一种节能模式相关的第一定时器;其中,该第一定时器设定该至少一种节能模式中的一种节能模式的作用时间。
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息通过第一定时器指示节能模式的作用时间,例如,300ms。
例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息,终端设备进行CSI测量方式更新,和/或,CSI上报更新,和/或,CSI-RS资源更新,和/或,BWP切换,并且在经过300ms后恢复正常模式,后续将结合指示信息指示的具体内容分别说明。
在一些实施方式中,网络设备通过半静态信令或动态信令发送该指示信息。
例如,如果采用RRC信令发送指示信息,例如采用RRC重配流程,其实现为毫秒量级,过大的时延不利于对动态节能模式的支持,动态节能模式可以是符号或者时隙级别的(小于毫秒);再例如,在通常情况下,一个用户的CSI-RS资源和CSI测量不需要频繁改变,但在节能操作过程中,正常模式和节能模式会频繁切换,如果使用RRC信令流程会带来很大的开销,以及造成系统资源的浪费。由此,本申请上述实施方式通过半静态信令或动态信令发送该指示信息能够进一步减少信令的时延和开销,以及能够支持动态节能模式的切换。
在一些实施方式中,半静态信令可以为MAC CE信令;动态信令可以为下行控制信息(Downlink control information,DCI)。例如,该动态信令为DCI,指示信息通过该DCI承载,该DCI可以为节能模式新增的DCI格式(DCI format),也可以重 用现有的DCI格式,本申请对此不进行限制,例如,在引入新增的DCI格式(DCI format)的情况下,可以通过引入新的无线网络临时标识(Radio Network Temporary Identity,RNTI),例如ES-RNTI(energy saving-RNTI)对该DCI格式进行加扰,也可以为该新的DCI格式划分特定的时频资源以便终端设备能够识别该DCI,本申请对此不进行限制。
在一些实施方式中,该指示信息可以通过指示改变服务模式的信令一并发送给终端设备;例如,通过DCI对终端设备指示激活/去激活“节能模式”,可以通过该DCI一并携带该指示信息;可选的,该指示信息也可以与指示改变服务模式的信令分别发送,本申请对此不进行限制。
在一些实施方式中,该半静态信令或该动态信令为组(Group)信令,网络设备通过该组信令向多个终端设备发送指示信息;或者,该半静态信令或该动态信令为终端设备特定(UE specific)信令,网络设备通过该用户设备特定信令向一个终端设备发送指示信息。
在一些实施方式中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。以下将示意性对上述指示信息的指示分别说明。
以下对于如何指示CSI测量方式更新进行具体说明。
例如,“CSI测量方式”为终端设备对CSI测量结果进行“合并处理”或者“不合并处理”;例如,“合并处理”也可以替换为“合并平均”或者“平滑滤波”;其中,“合并处理”或者“平滑滤波”的具体实施方式可以参见现有的技术,本申请对此不进行限制。
例如,在“正常模式”(“非节能模式”)下,终端设备通常会对所有CSI测量结果进行合并处理;但是,在开启“节能模式”的情况下,信道状态指示参考信号(CSI-RS)的传输功率会发生变化,在“正常模式”向“节能模式”变更之后的最近一次CSI测量方式也应该相应地变化,来实时反映信道质量状态。例如,在“正常模式”变更为“节能模式”时,如果终端设备仍然对CSI测量结果做合并处理,可能会对“正常模式”和“节能模式”的CSI测量结果进行合并,因此会导致合并后的CSI测量结果无法真实地反映节能模式的信道状态。而本申请实施方式能够通过该指示信息使得终端设备及时获取CSI测量方式更改或者不更改,由此,能够更加准确的进行CSI测量。
在一些实施方式中,网络设备通过指示CSI测量方式更新的指示信息和/或第一定时器指示CSI测量方式更改或者不更改。
在一些实施方式中,在网络设备改变服务模式的情况下,该指示信息通过一个或多个比特的一个取值指示更改CSI测量方式,和/或,通过该一个或多个比特的另一个取值指示不更改所述CSI测量方式。
在一些实施方式中,在半静态信令或动态信令为组信令的情况下,该指示信息为包括多个块的位图(bitmap)。
例如,每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置。
图3为本申请实施例指示信息的一示例图。
例如,每个块(block)代表一个终端设备的指示信息,每个块(block)的起始位置和/或大小由高层参数给出,例如可以使用现有标准中的高层参数,也可以引入新的高层参数,本申请对此不进行限制。
以每个块为1比特为例,其中,网络设备可以通过1比特来指示特定终端设备CSI测量方式更改或者不更改,例如,该比特为“1”,为更改该CSI测量方式,也可以说,不进行CSI测量合并处理;该比特为“0”,为不更改该CSI测量方式,也可以说,进行CSI测量合并处理。
例如,对于五个终端设备,指示信息的具体内容为“11010”的含义即为:对于第一个、第二个、第四个终端设备,不进行CSI测量合并处理;对于第三个、第五个终端设备,进行CSI测量合并处理。以第三个终端设备为例,该第三个终端设备通过高层信令获得该指示信息一共为5比特,其中,每个块的大小为1比特,因此该第三个终端设备可以确定第三个比特(取值为“0”)为该第三个终端设备的指示比特。
在一些实施方式中,如果终端设备的CSI测量方式发生更改,该指示信息携带该终端设备对应的块;如果终端设备的CSI测量方式不发生更改,该指示信息不携带该终端设备对应的块。例如,该终端设备通过高层信令未读取到该指示信息的相关字段,则认为CSI测量方式不更改,仍然使用原本的CSI测量方式。
在一些实施方式中,在半静态信令或动态信令为终端设备特定信令的情况下。例如,网络设备可以通过1比特来指示CSI测量方式更改或者不更改,例如,该比特为“1”,为更改该CSI测量方式,也可以说,不进行CSI测量合并处理;该比特为“0”,为不更改该CSI测量方式,也可以说,进行CSI测量合并处理。
上述比特内容仅为示例性说明,也可以设置为比特为“0”,为更改该CSI测量方式,也可以说,不进行CSI测量合并处理;该比特为“1”,为不更改该CSI测量方式,本申请对此不进行限制。
在一些实施方式,终端设备在第一定时器超时后更改CSI测量方式。
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息指示节能模式的作用时间。例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息(采用上述的指示方法),终端设备进行CSI测量方式更新,例如正常模式变更到节能模式时不进行合并处理,并且在经过300ms后恢复正常模式,以及更改CSI测量方式,例如,300ms到期时的CSI测量不进行合并处理。
由此,终端设备能够获取指示信息的具体内容,能够更加准确的进行CSI测量。
以下对于如何指示CSI上报更新进行具体说明。
在一些实施方式中,网络设备通过指示CSI上报更新的指示信息和/或第一定时器激活/去激活至少一个CSI上报。
在一些实施方式中,在网络设备改变服务模式的情况下,指示信息指示激活第一CSI上报和/或去激活第二CSI上报,其中,该第一CSI上报和/或该第二CSI上报由高层信息配置。
在一些实施方式中,该第一CSI上报和/或该第二CSI上报属于第一CSI上报列表,该第一CSI上报列表包括CSI上报配置索引(CSI-ReportConfigId),其中,该第一CSI上报列表和该CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
例如,每个CSI上报与CSI上报配置索引(CSI-ReportConfigId)对应,例如,CSI上报配置索引(CSI-ReportConfigId)=0对应的CSI上报为:CSI 0。
例如,该第一CSI上报列表包含哪些CSI上报是通过高层信令配置的,例如,高层信令配置第一CSI上报列表包含5个CSI上报,分别对应“CSI 0”-“CSI 4”;终端设备根据指示信息确定激活/去激活哪个具体的CSI上报,说明书将在后续内容将进一步结合实施方式举例说明。
在一些实施方式中,该第一CSI上报列表包括的CSI上报配置索引(CSI-ReportConfigId)与以下至少一个信息的变更关联:
CSI上报周期以及偏移(offset),例如通过高层信令的如下字段指示“CSI-ReportPeriodicityAndOffset”,“reportSlotConfig”和“reportSlotOffsetList”;
CSI上报使用的资源,例如通过高层信令的如下字段指“pucch-CSI-ResourceList”指示;
CSI上报绑定的CSI-RS Resource的周期以及偏移(offset),例如通过高层信令的如下字段指示“ResourceConfig”;或CSI-
CSI上报绑定的CSI-RS Resource的时频资源,例如通过高层信令的如下字段指示“CSI-ResourceConfig”。
例如,在节能模式下的CSI上报的周期可以较长,例如,正常模式下的CSI上报周期为40ms,节能模式下的CSI周期为80m;例如,高层配置了CSI 0的周期为80ms,CSI 1的周期为40ms,以及第一CSI上报列表包括CSI 0和CSI 1,在服务模式改变为节能模式后,指示信息可以指示激活CSI 0(第一CSI上报)以及去激活CSI 1(第二CSI上报),说明书将在后续内容将进一步结合实施方式举例说明。
再例如,在节能模式下的CSI上报绑定的CSI-RS资源为CSI-RS 16port,正常模式下的CSI上报绑定的CSI-RS资源为CSI-RS 32port,例如,高层配置了CSI 0绑定32port的CSI-RS 0,CSI 1绑定16port的CSI-RS 1,以及第一CSI上报列表包括CSI 0和CSI 1,在服务模式改变为节能模式后,指示信息可以指示激活CSI 1(第一CSI上报)以及去激活CSI 0(第二CSI上报),激活CSI 1也意味着同样激活其绑定的16port的CSI-RS 1,去激活CSI 0也意味着同样去激活其绑定的32port的CSI-RS 0。
在一些实施方式中,对于一个特定CSI上报,指示信息通过一个或多个比特的一个取值指示激活该CSI上报,通过该一个或多个比特的另一个取值指示去激活该CSI上报。
在一些实施方式中,在半静态信令或动态信令为组信令的情况下,该指示信息为包括多个块的位图;其中,每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置,每个块包括一个或多个比特,每个块指示终端设备的该第一CSI上报列表,每个块中的每个比特对应该第一CSI上报列表中的CSI上报。
例如,仍然以图3所示的多个块的位图为例,每个块(block)代表一个终端设备的指示信息,每个块(block)的起始位置和/或大小由高层参数给出,例如可以使 用现有标准中的高层参数,也可以引入新的高层参数,本申请对此不进行限制。
例如,每个块(block)对应一个特定终端设备的第一CSI上报列表,每个块例如包括X比特,其中,该X比特的每一个比特对应该第一CSI上报列表中的一个CSI上报的激活/去激活的状态,该列表可以由高层参数给出。
以一个特定终端设备为例,例如,高层参数配置了第一CSI上报列表包含5个CSI上报,分别对应“CSI 0”-“CSI 4”,通过5个比特指示每个CSI上报的激活/去激活状态,例如,“0”代表去激活CSI上报,“1”代表激活CSI上报;例如,高层参数配置了“CSI 0”(第一CSI上报)的CSI周期为80m,“CSI 1”-“CSI 4”(第二CSI上报)的CSI周期为40m,可以发送“10000”给用户设备,其含义为激活“CSI 0”,去激活“CSI 1”-“CSI 4”。
例如,对于五个终端设备,指示信息为“‘10000’‘10100’‘00011’‘00100’‘10001’”;以第二个终端设备为例,该第二个终端设备通过高层信令获得该指示信息一共为25比特,起始位置为第6比特,并且本终端指示信息大小为5比特,即第六至第十比特为该第二个终端设备的指示比特;其中,‘10100’指示的是对于第二个终端设备,激活“CSI 0”(第一CSI上报)以及“CSI 2”(第一CSI上报),去激活“CSI 1”(第二CSI上报)、“CSI 3”(第二CSI上报)、“CSI 4”(第二CSI上报)。以上仅为示例性说明,例如,对于不同的终端设备的第一CSI上报列表可以不同。
在一些实施方式中,如果终端设备的CSI上报激活/去激活状态需要更新,该指示信息携带该终端设备对应的块;如果终端设备的CSI上报激活/去激活状态不需要更新,该指示信息不携带该终端设备对应的块。例如,该终端设备通过高层信令未读取到该指示信息的相关字段,则认为CSI上报激活/去激活状态不需要更新。
上述比特内容仅为示例性说明,也可以设置“0”代表激活CSI上报,“1”代表去激活CSI上报,本申请对此不进行限制。
在一些实施方式中,该第一CSI上报和/或该第二CSI上报包括:周期性的CSI上报、半持续的CSI上报、或非周期性的CSI上报;例如,周期性的CSI上报、半持续的CSI上报、或非周期性的CSI上报的具体内容可以参见现有技术,本申请对此不进行限制。
图4是本申请实施例CSI上报的一示例图。
例如,对于一个特定终端设备,在终端设备处于正常模式的情况下,其被配置的 CSI上报为“CSI 0”,其绑定的CSI-RS资源为“CSI-RS 0”;在终端设备处于节能模式的情况下其被配置的CSI上报为“CSI 1”,其绑定的CSI-RS资源为“CSI-RS 1”;例如,结合上述更新CSI上报的方法,在改变服务模式进入节能模式的情况下,网络设备发送的指示信息为“…‘01000’….”,对应更新的激活的CSI上报为“CSI 1”;例如,在改变服务模式进入正常模式的情况下,发送的指示信息为“…‘10000’….”,对应更新的激活的CSI上报为“CSI 0”。
在一些实施方式中,在半静态信令或动态信令为终端设备特定信令的情况下。例如,网络设备可以通过X比特来指示第一CSI上报列表;该X比特中的每个比特指示具体的激活CSI上报或者去激活CSI上报,例如,“1”为激活CSI上报;“0”为去激活CSI上报。例如,采用上述实施方式的每个块的内容作为终端设备特定信令的具体内容进而发送给特定的终端设备,对于具体的指示方法可以参见上述实施方式,在此不做重复说明。
在一些实施方式,终端设备在服务模式变更时,开启第一定时器并挂起服务模式改变前的CSI上报;以及该终端设备在第一定时器超时后恢复该服务模式改变前的CSI上报
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息指示节能模式的作用时间。例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息(采用上述的指示方法),终端设备更新了激活/去激活的CSI上报并且挂起正常模式下激活/去激活的CSI上报,并且在经过300ms,即第一定时器超时后恢复正常模式,以及恢复正常模式下激活/去激活的CSI上报。
由此,终端设备能够获取指示信息的具体内容,能够确定CSI上报更新。
以下对于如何指示CSI-RS资源更新进行具体说明。
在一些实施方式中,网络设备通过指示CSI-RS资源更新的指示信息和/或第一定时器激活/去激活至少一个CSI-RS资源。
在一些实施方式中,在网络设备改变服务模式的情况下,指示信息指示激活第一CSI-RS资源和/或去激活第二CSI-RS资源,其中,该第一CSI-RS资源和/或该二CSI-RS资源由高层信息配置;其中,该第一CSI-RS资源和/或所述第二CSI-RS资源是相同的或是不同的。
在一些实施方式中,该第一CSI-RS资源和/或该第二CSI-RS资源属于第一CSI-RS资源集合,其中,该第一CSI-RS资源集合包括CSI-RS资源(CSI-RS resource),和/或,CSI-RS端口(CSI-RS port);其中,该第一CSI-RS资源集合的索引以及该第一CSI-RS资源集合包括的CSI-RS资源(CSI-RS resource)的个数和索引,和/或,该CSI-RS端口(CSI-RS port)的个数和/或索引由高层信息配置。
例如,高层信令配置了该第一CSI-RS资源集合及其索引,以及该第一CSI-RS资源集合下包含多个CSI-RS resource和多个CSI-RS port以及相关配置,其中,多个CSI-RS resource和多个CSI-RS port相关配置可以参见现有技术,本申请对此不进行限制。
以下以该第一CSI-RS资源和/或该第二CSI-RS资源属于第一CSI-RS资源集合,其中,该第一CSI-RS资源集合包括CSI-RS资源(CSI-RS resource)为例。
在一些实施方式中,对于一个特定CSI-RS资源(CSI-RS resource),指示信息通过一个或多个比特的一个取值指示激活CSI-RS资源(CSI-RS resource),该指示信息通过一个或多个比特的另一个取值指示去激活CSI-RS资源(CSI-RS resource)。
在一些实施方式中,该CSI-RS资源(CSI-RS resource)包括一组CSI-RS资源(CSI-RS resource)或者一个CSI-RS资源(CSI-RS resource),该一组CSI-RS资源(CSI-RS resource)由高层信令配置。
在一些实施方式中,在半静态信令或动态信令为组信令的情况下,该指示信息为包括多个块的位图;其中每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置;每个比特对应该终端设备的一组CSI-RS资源(CSI-RS resource)或者一个CSI-RS资源(CSI-RS resource),该比特的个数由高层信令配置。
例如,仍然以图3所示的多个块的位图为例,每个块(block)代表一个终端设备的指示信息,每个块(block)的起始位置和/或大小由高层参数给出,例如可以使用现有标准中的高层参数,也可以引入新的高层参数,本申请对此不进行限制。
例如,每个块(block)对应一个特定终端设备的一个CSI-RS资源集合(CSI-RS resource set)中的各个CSI-RS资源(CSI-RS resource)的激活/去激活的状态,例如,每个块包括X比特,其中该X比特的每一个比特对应CSI-RS资源(CSI-RS resource)的激活/去激活的状态。在一些实施方式中,CSI-RS资源集合(CSI-RS resource set)及其对应的CSI-RS资源(CSI-RS resource)的具体设置可以参见现有技术,本申请 对此不进行限制。
例如,第一CSI-RS资源集合(CSI-RS resource set)中包括4个CSI-RS资源(CSI-RS resource),通过4个比特指示每个CSI-RS资源(CSI-RS resource)的激活/去激活状态,例如,“0”代表去激活该CSI-RS资源(CSI-RS resource),“1”代表激活该CSI-RS资源(CSI-RS resource);“1010”的含义为激活“CSI-RS资源0”(第一CSI-RS资源)、“CSI-RS资源2”(第一CSI-RS资源),去激活“CSI-RS资源1”(第二CSI-RS资源)、“CSI-RS资源3”(第二CSI-RS资源)。
例如,对于两个终端设备,指示信息为“‘1010’‘0101’”;以第一个终端设备为例,该第一个终端设备通过高层信令获得该指示信息一共为8比特起始位置为第1比特,并且持续4比特,即第一至第四比特为该第一个终端设备的指示比特;其中,‘1010’指示的是对于第一个终端设备,激活“CSI-RS资源0”、“CSI-RS资源2”,去激活“CSI-RS资源1”、“CSI-RS资源3”。
可选的,该指示信息还可以指示一组CSI-RS资源(CSI-RS resource)的激活/去激活状态,例如,“CSI-RS资源0”、“CSI-RS资源2”为组0(Group 0);“CSI-RS资源1”、“CSI-RS资源3”为组1(Group 1);对于两个终端设备,指示信息为“‘10’‘01’”;以第一个终端设备为例,该第一个终端设备通过高层信令获得该指示信息一共为4比特,其中,每个块的大小为2比特以及“CSI-RS资源0”、“CSI-RS资源2”为组0(Group 0),“CSI-RS资源1”、“CSI-RS资源3”为组1(Group 1),并且第一至第二比特为该第一个终端设备的指示比特;其中,‘10’指示的是对于第一个终端设备,激活“CSI-RS资源0”、“CSI-RS资源2”,去激活“CSI-RS资源1”、“CSI-RS资源3”。
在一些实施方式中,如果终端设备的CSI-RS资源(CSI-RS resource)的激活/去激活状态需要更新,该指示信息携带该终端设备对应的块;如果终端设备的CSI-RS资源(CSI-RS resource)的激活/去激活状态不需要更新,该指示信息不携带该终端设备对应的块。例如,该终端设备通过高层信令未读取到该指示信息的相关字段,则认为CSI-RS资源(CSI-RS resource)的激活/去激活状态不需要更新。
上述比特内容仅为示例性说明,也可以设置“0”代表激活CSI-RS资源(CSI-RS resource),“1”代表去激活CSI-RS资源(CSI-RS resource),本申请对此不进行限制。
图5是本申请实施例CSI-RS resource更新的一示例图。
如图5所示,对于32端口CSI-RS,例如,可以通过CDM-4以及4个resource的方式来支持32端口CSI-RS,其中,CDM-4的一个resource占据8个资源元素(resource element,RE),CDM-4可以参考现有技术,本申请对此不进行限制。在正常模式下,特定终端设备采用32端口CSI-RS,在节能模式下,该终端设备采用16端口CSI-RS,例如,在网络设备关闭部分空域元素的情况下,终端设备的CSI-RS资源由图5中的激活“资源1(Resource 1)-资源4(Resource 4)”变更为激活“资源1(Resource 1)、资源3(Resource3)”,去激活“资源2(Resource 2)、资源4(Resource4)”。由此,能够实现32port CSI-RS资源到16port CSI-RS资源的更新;例如,采用上述指示的方式,在此不做重复说明。
在一些实施方式中,在半静态信令或动态信令为终端设备特定信令的情况下。例如,网络设备可以通过X比特来指示一个CSI-RS资源集合(CSI-RS resource set)包含的CSI-RS资源(CSI-RS resource)的激活/去激活状态;该X比特中的每个比特指示具体的CSI-RS资源(CSI-RS resource)的激活/去激活状态,例如,“1”为激活CSI-RS资源(CSI-RS resource);“0”为去激活CSI-RS资源(CSI-RS resource);可选的,网络设备可以通过X比特来指示一个CSI-RS资源集合(CSI-RS resource set)包含的多组CSI-RS资源(CSI-RS resource)的激活/去激活状态。例如,采用上述实施方式的每个块的内容作为终端设备特定信令的具体内容进而发送给特定的终端设备,对于具体的指示方法可以参见上述实施方式,在此不做重复说明。
在一些实施方式,终端设备在第一定时器超时后挂起服务模式改变前的CSI-RS资源;以及该终端设备在第一定时器超时后恢复该服务模式改变前的CSI-RS资源。
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息指示节能模式的作用时间。例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息(采用上述的指示方法),终端设备更新激活/去激活的CSI-RS资源并且挂起正常模式激活/去激活的CSI-RS资源,并且在经过300ms第一定时器超时后恢复正常模式,以及恢复正常模式下激活/去激活的CSI-RS资源。
由此,终端设备能够获取指示信息的具体内容,能够确定更新的激活/去激活的CSI-RS资源(CSI-RS resource)。
以下以该第一CSI-RS资源和/或该第二CSI-RS资源属于第一CSI-RS资源集合, 其中,该第一CSI-RS资源集合包括CSI-RS端口(CSI-RS port)为例。
在一些实施方式中,指示信息通过一个或多个比特的一个取值指示去激活该CSI-RS端口,通过该一个或多个比特的另一个取值指示激活该CSI-RS端口。
在一些实施方式中,CSI-RS端口包括一组CSI-RS端口或者一个CSI-RS端口;该一组CSI-RS端口由高层信令配置。
在一些实施方式中,在半静态信令或动态信令为组信令的情况下,指示信息为包括多个块的位图;其中,每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置;其中,每个块包括一个或多个比特,每个比特对应所述终端设备的一组CSI-RS端口或者一个CSI-RS端口,所述比特的个数由高层信令配置。
例如,仍然以图3所示的多个块的位图为例,每个块(block)代表一个终端设备的指示信息,每个块(block)的起始位置和/或大小由高层参数给出,例如可以使用现有标准中的高层参数,也可以引入新的高层参数,本申请对此不进行限制。
例如,每个块(block)对应一个特定终端设备的CSI-RS端口(port)的激活/去激活的状态,例如,每个块例如包括X比特,其中该X比特的每一个比特对应CSI-RS端口(port)的激活/去激活的状态。在一些实施方式中,CSI-RS端口(port)的具体设置可以参见现有技术,本申请对此不进行限制。
可选的,该每个块例还可以包括CSI-RS资源(CSI-RS resource)相关信息,例如包括T比特(T可以等于0),该T比特指示CSI-RS端口(port)对应的CSI-RS资源组(CSI-RS resource set)和/或CSI-RS资源(CSI-RS resource),可选的在T=0的情况下,CSI-RS端口(port)对应的CSI-RS资源组(CSI-RS resource set)和/或CSI-RS资源(CSI-RS resource)由高层信息指示。
以下以T=0,即,不指示CSI-RS端口(port)对应的CSI-RS资源组(CSI-RS resource set)和/或CSI-RS资源(CSI-RS resource)作为示例进行说明。
例如,对于一个终端设备能够被配置32CSI-RS端口,通过32个比特指示CSI-RS端口的激活/去激活状态,例如,“0”代表去激活该CSI-RS端口,“1”代表激活该CSI-RS端口;“00000000000000001111111111111111”的含义为激活“CSI-RS端口16”-“CSI-RS端口31”,去激活“CSI-RS端口0”-“CSI-RS端口15”;可选的,该指示信息还可以指示一组CSI-RS端口的激活/去激活状态,这一组CSI-RS端口可以是一个或多个CDM组,例如,“CSI-RS端口0”-“CSI-RS端口15”为组0(Group 0); “CSI-RS端口16”-“CSI-RS端口31”为组1(Group 1),或者CSI-RS32端口共4个CDM组,“CDM组0”和“CDM组1”为组0(Group 0),“CDM组2”和“CDM组3”为组1(Group 1)。
例如,对于两个终端设备,指示信息为“‘10’‘01’”;以第一个终端设备为例,该第一个终端设备通过高层信令获得该指示信息一共为4比特,该终端设备对应的起始位置为第1比特,共2比特以及“CSI-RS端口0”-“CSI-RS端口15”为组0(Group0);“CSI-RS端口16”-“CSI-RS端口31”为组1(Group 1),并且第一至第二比特为该第一个终端设备的指示比特;其中,‘10’指示的是对于第一个终端设备,激活“CSI-RS端口0”-“CSI-RS端口15”,去激活“CSI-RS端口16”-“CSI-RS端口31”。
此外,对于T不等于0的情况,可以结合上述激活/去激活CSI-RS端口(port)和上述激活/去激活CSI-RS resource的方式进行指示,本申请在此不做重复。
在一些实施方式中,如果终端设备的CSI-RS端口的激活/去激活状态需要更新,该指示信息携带该终端设备对应的块;如果终端设备的CSI-RS端口不需要更新,该指示信息不携带该终端设备对应的块。例如,该终端设备通过高层信令未读取到该指示信息的相关字段,则认为CSI-RS端口的激活/去激活状态不需要更新。
上述比特内容仅为示例性说明,也可以设置“0”代表激活CSI-RS端口,“1”代表去激活CSI-RS端口,本申请对此不进行限制。
图6是本申请实施例CSI-RS端口更新的一示例图。
如图6所示,对于32端口CSI-RS,例如,可以通过4个CDM-8以及1个resource的方式来支持32端口CSI-RS,其中,CDM-8的一个resource占据32个资源元素(resource element,RE),CDM-8可以参考现有技术,本申请对此不进行限制。在正常模式下,特定终端设备采用32端口CSI-RS,在节能模式下,该终端设备采用16端口CSI-RS,例如,在网络设备关闭部分空域元素的情况下,终端设备的CSI-RS资源由图6中的“激活CSI-RS端口0-31”变更为“激活CSI-RS端口0-15”由此,能够实现32port CSI-RS到16port CSI-RS的更新;例如,采用上述指示的方式,在此不做重复说明。
在一些实施方式中,在半静态信令或动态信令为终端设备特定信令的情况下。例如,网络设备可以通过X比特来指示CSI-RS端口激活/去激活状态;该X比特中的每个比特指示具体的CSI-RS端口的激活/去激活状态,例如,“1”为激活CSI-RS端 口;“0”为去CSI-RS资源(CSI-RS resource);可选的,网络设备可以通过X比特来指示多组CSI-RS端口的激活/去激活状态。例如,采用上述实施方式的每个块的内容作为终端设备特定信令的具体内容进而发送给特定的终端设备,对于具体的指示方法可以参见上述实施方式,在此不做重复说明。
在一些实施方式,终端设备在第一定时器超时后挂起服务模式改变前的CSI-RS端口;以及该终端设备在第一定时器超时后恢复该服务模式改变前的CSI-RS端口。
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息指示节能模式的作用时间。例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息(采用上述的指示方法),终端设备更新激活/去激活CSI-RS端口并且挂起正常模式的激活/去激活的CSI-RS端口,并且在经过300ms第一定时器超时后恢复正常模式,以及恢复正常模式下激活/去激活的CSI-RS端口。
由此,终端设备能够获取指示信息的具体内容,能够确定更新的激活/去激活的CSI-RS端口(CSI-RS端口)。
以下对于如何指示BWP切换进行具体说明。
在一些实施方式中,网络设备通过指示BWP切换的指示信息和/或第一定时器指示服务模式变更后的BWP。
在一些实施方式中,在网络设备改变服务模式的情况下,指示信息指示服务模式变更后的BWP索引;其中,该BWP索引由高层信息配置。
在一些实施方式中,BWP索引与CSI上报配置索引(CSI-ReportConfigId)关联;其中,该BWP索引关联的所述CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
在一些实施方式中,在网络设备改变服务模式的情况下,切换至激活服务模式变更后的BWP索引对应的BWP,同时激活关联的CSI上报配置索引(CSI-ReportConfigId)关联的CSI上报,去激活服务模式变更前的BWP索引关联的CSI上报配置索引(CSI-ReportConfigId)关联的CSI上报。
在一些实施方式中,在半静态信令或动态信令为组信令的情况下,该指示信息为包括多个块的位图;其中每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置;其中,每个块包括一个或多个比特,指示终端设备该切换的BWP的 索引(index)。
例如,仍然以图3所示的多个块的位图为例,每个块(block)代表一个终端设备的指示信息,每个块(block)的起始位置和/或大小由高层参数给出,例如可以使用现有标准中的高层参数,也可以引入新的高层参数,本申请对此不进行限制。
例如,每个块(block)对应开启或关闭至少一部分空域元素的情况下,终端设备即将要切换的BWP的索引(index),例如,每个块包括X比特,其对应一个BWP的索引。在一些实施方式中,BWP的设置和其索引可以参见现有技术,本申请对此不进行限制。
例如,一个终端设备被配置了4个BWP,指示信息通过2个比特指示切换的BWP索引,例如,“00”代表切换到BWP 0,“01”代表切换到BWP 1,“10”代表切换到BWP 2,“11”代表切换到BWP 3。例如,高层信令配置了BWP 0与CSI 0关联,BWP 1与CSI1关联,在服务模式变更为节能模式后,例如指示信息指示了“00”下,对应激活CSI 0,去激活终端设备正常模式下的CSI上报,例如,去激活高层信令配置的正常模式下的CSI 1。
例如,对于两个终端设备,在服务模式变更的情况下,指示信息为“‘10’‘01’”;以第一个终端设备为例,该第一个终端设备通过高层信令获得该指示信息一共为4比特,其中,每个块的大小为2比特,并且第一至第二比特为该第一个终端设备的指示比特;其中,‘10’指示的是对于第一个终端设备,切换到BWP 2。
在一些实施方式中,如果终端设备的BWP需要切换,该指示信息携带该终端设备对应的块;如果终端设备的BWP不需要切换,该指示信息不携带该终端设备对应的块。例如,该终端设备通过高层信令未读取到该指示信息的相关字段,则认为终端设备的BWP不需要切换。
在一些实施方式,终端设备挂起服务模式改变前的BWP索引;以及终端设备在第一定时器超时后恢复服务模式改变前的BWP索引。
例如,网络设备通过高层信令,例如RRC信令,发送该配置信息,其中,该配置信息指示节能模式的作用时间。例如,终端设备读取RRC信令后获取该节能模式的作用时间,网络设备改变服务模式(例如,从正常模式进入节能模式)并向终端设备发送指示信息(采用上述的指示方法),终端设备切换的BWP索引并且挂起正常模式下的BWP索引,并且在经过300ms第一定时器超时后恢复正常模式,切换回正常 模式下的BWP索引。
由此,终端设备能够获取指示信息的具体内容,能够确定切换的BWP索引。
值得注意的是,以上附图4-图6仅对本申请实施例进行了示意性说明,但本申请不限于此。例如可以适当地调整各个操作之间的执行顺序,此外还可以增加其他的一些操作或者减少其中的某些操作。本领域的技术人员可以根据上述内容进行适当地变型,而不仅限于上述附图4-图6的记载。
由上述实施例可知,网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
第二方面的实施例
本申请实施例提供一种信息接收方法,从终端设备侧进行说明,与第一方面的实施例的重复部分不再赘述。
图7是本申请实施例的信息接收方法的一示意图,如图7所示,该方法包括:
701,终端设备接收指示信息;
702,终端设备根据所述指示信息确定:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
在一些实施方式中,服务模式包括正常模式和/或至少一种节能模式。
在一些实施方式中,终端设备还接收配置信息,其中,配置信息配置与该至少一种节能模式中的一种节能模式相关的第一定时器;其中,该第一定时器设定该至少一种节能模式中的一种节能模式的作用时间。
在一些实施方式中,终端设备通过半静态信令或动态信令接收指示信息;其中,
该半静态信令或该动态信令为组信令,网络设备通过该组信令向多个终端设备发送所述指示信息;或者,该半静态信令或动态信令为用户设备特定信令,该网络设备通过该用户设备特定信令向一个终端设备发送所述指示信息。
值得注意的是,以上附图7仅对本申请实施例进行了示意性说明,但本申请不限于此。例如可以适当地调整各个操作之间的执行顺序,此外还可以增加其他的一些操作或者减少其中的某些操作。本领域的技术人员可以根据上述内容进行适当地变型,而不仅限于上述附图7的记载。
由上述实施例可知,网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
第三方面的实施例
本申请实施例提供一种信息指示装置。该装置例如可以是网络设备,也可以是配置于网络设备的某个或某些部件或者组件,与第一方面的实施例相同的内容不再赘述。
图8是本申请实施例中信息指示装置800的一示意图,如图8所示,该信息指示装置800包括:
变更单元801,其改变服务模式;
发送单元802,其向终端设备发送指示信息,其中,该指示信息指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
在一些实施方式中,服务模式包括正常模式和/或至少一种节能模式。
在一些实施方式中,发送单元802还发送配置信息给终端设备,其中,该配置信息配置与该至少一种节能模式中的一种节能模式相关的第一定时器;其中,该第一定时器设定该至少一种节能模式中的一种节能模式的作用时间。
在一些实施方式中,发送单元802通过半静态信令或动态信令发送该指示信息;其中,半静态信令或动态信令为组信令,网络设备通过该组信令向多个终端设备发送该指示信息;或者半静态信令或动态信令为用户设备特定信令,网络设备通过该用户设备特定信令向一个终端设备发送该指示信息。
在一些实施方式中,网络设备通过指示CSI测量方式更新的指示信息和/或第一 定时器指示CSI测量方式更改或者不更改。
在一些实施方式中,在网络设备改变服务模式的情况下,指示CSI测量方式更新的该指示信息通过一个或多个比特的一个取值指示更改该CSI测量方式,和/或,通过该一个或多个比特的另一个取值指示不更改该CSI测量方式。
在一些实施方式中,终端设备在该第一定时器超时后更改CSI测量方式。
在一些实施方式中,网络设备通过指示CSI上报更新的指示信息和/或第一定时器激活/去激活至少一个CSI上报。
在一些实施方式中,在网络设备改变该服务模式的情况下,指示CSI上报更新的指示信息指示激活第一CSI上报和/或去激活第二CSI上报,其中,该第一CSI上报和/或该第二CSI上报由高层信息配置。
在一些实施方式中,终端设备挂起服务模式改变前的CSI上报;以及该终端设备在该第一定时器超时后恢复该服务模式改变前的CSI上报。
在一些实施方式中,该第一CSI上报和/或该第二CSI上报属于第一CSI上报列表,该第一CSI上报列表包括CSI上报配置索引(CSI-ReportConfigId),其中,该第一CSI上报列表和该CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
在一些实施方式中,其中,该第一CSI上报和/或该第二CSI上报包括:周期性的CSI上报、半持续的CSI上报、或非周期性的CSI上报。
在一些实施方式中,该第一CSI上报列表包括的该CSI上报配置索引(CSI-ReportConfigId)与以下至少一个信息的变更关联:CSI上报周期以及偏移(offset);CSI上报使用的资源;CSI上报绑定的CSI-RS Resource的周期以及偏移(offset);或CSI上报绑定的CSI-RS Resource的时频资源。
在一些实施方式中,网络设备通过指示CSI-RS资源更新的该指示信息和/或该第一定时器激活/去激活至少一个CSI-RS资源。
在一些实施方式中,在网络设备改变该服务模式的情况下,指示CSI-RS资源更新的该指示信息指示激活第一CSI-RS资源和/或去激活第二CSI-RS资源,其中,该第一CSI-RS资源和/或该二CSI-RS资源由高层信息配置;其中,该第一CSI-RS资源和/或该第二CSI-RS资源是相同的或是不同的。
在一些实施方式中,终端设备挂起该服务模式改变前的CSI-RS资源;以及终端设备在该第一定时器超时后恢复该服务模式改变前的CSI-RS资源。
在一些实施方式中,第一CSI-RS资源和/或第二CSI-RS资源属于第一CSI-RS资源集合,其中,该第一CSI-RS资源集合包括CSI-RS资源(CSI-RS resource),和/或,CSI-RS端口(CSI-RS port);其中,该第一CSI-RS资源集合的索引以及该第一CSI-RS资源集合包括的CSI-RS资源(CSI-RS resource)的个数和索引,和/或,该CSI-RS端口(CSI-RS port)的个数和/或索引由高层信息配置。
在一些实施方式中,网络设备通过指示BWP切换的该指示信息和/或该第一定时器指示该服务模式变更后的BWP。
在一些实施方式中,在网络设备改变该服务模式的情况下,指示BWP切换的该指示信息指示该服务模式变更后的BWP索引;其中,该BWP索引由高层信息配置。
在一些实施方式中,终端设备还挂起该服务模式改变前的BWP索引;以及该终端设备在该第一定时器超时后恢复该服务模式改变前的BWP索引。
在一些实施方式中,BWP索引与CSI上报配置索引(CSI-ReportConfigId)关联;其中,该BWP索引关联的该CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
在一些实施方式中,在该网络设备改变该服务模式的情况下,切换至激活服务模式变更后的部分带宽(BWP)索引对应的BWP,同时激活关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报,去激活该服务模式变更前的部分带宽(BWP)索引关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报。
在一些实施方式中,在该半静态信令或动态信令为组信令的情况下,该指示信息为包括多个块的位图;其中每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置。
图8中的信息指示装置的实施方式可以参考第一方面的实施例,此处不再赘述。
以上各个实施例仅对本申请实施例进行了示例性说明,但本申请不限于此,还可以在以上各个实施例的基础上进行适当的变型。例如,可以单独使用上述各个实施例,也可以将以上各个实施例中的一种或多种结合起来。
值得注意的是,以上仅对与本申请相关的各部件或模块进行了说明,但本申请不限于此。信息指示装置800还可以包括其它部件或者模块,关于这些部件或者模块的具体内容,可以参考相关技术。
此外,为了简单起见,图8中仅示例性示出了各个部件或模块之间的连接关系或信号走向,但是本领域技术人员应该清楚的是,可以采用总线连接等各种相关技术。上述各个部件或模块可以通过例如处理器、存储器、发射机、接收机等硬件设施来实现;本申请实施并不对此进行限制。
由上述实施例可知,网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
第四方面的实施例
本申请实施例提供一种信息接收装置。该装置例如可以是终端设备,也可以是配置于终端设备的某个或某些部件或者组件,与第二方面的实施例相同的内容不再赘述。
图9是本申请实施例中信息接收装置900的一示例图。如图9所示,该信息接收装置900包括:
接收单元901,其接收指示信息;
确定单元902,其根据所述指示信息确定:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
以上各个实施例仅对本申请实施例进行了示例性说明,但本申请不限于此,还可以在以上各个实施例的基础上进行适当的变型。例如,可以单独使用上述各个实施例,也可以将以上各个实施例中的一种或多种结合起来。
在一些实施方式中,该服务模式包括正常模式和/或至少一种节能模式。
在一些实施方式中,接收单元901还接收配置信息,其中,该配置信息配置与该至少一种节能模式中的一种节能模式相关的第一定时器;其中,该第一定时器设定所述至少一种节能模式中的一种节能模式的作用时间。
在一些实施方式中,接收单元901通过半静态信令或动态信令接收该指示信息;其中,该半静态信令或该动态信令为组信令,网络设备通过该组信令向多个终端设备 发送该指示信息;或者,该半静态信令或动态信令为用户设备特定信令,网络设备通过用户设备特定信令向一个终端设备发送该指示信息。
值得注意的是,以上仅对与本申请相关的各部件或模块进行了说明,但本申请不限于此。信息接收装置900还可以包括其它部件或者模块,关于这些部件或者模块的具体内容,可以参考相关技术。
此外,为了简单起见,图9中仅示例性示出了各个部件或模块之间的连接关系或信号走向,但是本领域技术人员应该清楚的是,可以采用总线连接等各种相关技术。上述各个部件或模块可以通过例如处理器、存储器、发射机、接收机等硬件设施来实现;本申请实施并不对此进行限制。
由上述实施例可知,网络设备改变服务模式以及向终端设备发送指示信息,其中,指示信息指示:CSI测量方式更新;和/或,CSI上报更新;和/或,CSI-RS资源更新;和/或,BWP切换。由此,终端设备通过指示信息能够没有歧义的适应改变的服务模式,以及准确的确定CSI测量方式更新和/或CSI上报更新和/或CSI-RS资源更新和/或BWP切换等信息,进一步高效的与网络设备进行后续上行数据的发送或者下行数据的接收。
第五方面的实施例
本申请实施例还提供一种通信系统,可以参考图1,与第一方面至第四方面的实施例相同的内容不再赘述。
在一些实施例中,通信系统100至少可以包括:终端设备102和/或网络设备101。
在一些实施例中,终端设备102的实施方式可以参考如下网络设备1000,网络设备101的实施方式可以参考如下终端设备1100。
本申请实施例还提供一种网络设备,例如可以是基站,但本申请不限于此,还可以是其它的网络设备。
图10是本申请实施例的网络设备的构成示意图。如图10所示,网络设备1000可以包括:处理器1010(例如中央处理器CPU)和存储器1020;存储器1020耦合到处理器1010。其中该存储器1020可存储各种数据;此外还存储信息处理的程序1030,并且在处理器1010的控制下执行该程序1030。
例如,处理器1010可以被配置为执行程序而实现如第一方面的实施例所述的信 息指示方法。
此外,如图10所示,网络设备1000还可以包括:收发机1040和天线1050等;其中,上述部件的功能与现有技术类似,此处不再赘述。值得注意的是,网络设备1000也并不是必须要包括图10中所示的所有部件;此外,网络设备1000还可以包括图10中没有示出的部件,可以参考现有技术。
本申请实施例还提供一种终端设备,但本申请不限于此,还可以是其它的设备。
图11是本申请实施例的终端设备的示意图。如图11所示,该终端设备1100可以包括处理器1110和存储器1120;存储器1120存储有数据和程序,并耦合到处理器1110。值得注意的是,该图是示例性的;还可以使用其它类型的结构,来补充或代替该结构,以实现电信功能或其它功能。
例如,处理器1110可以被配置为执行程序而实现如第二方面的实施例所述的信息接收方法。
如图11所示,该终端设备1100还可以包括:通信模块1130、输入单元1140、显式器1150、电源1160。其中,上述部件的功能与现有技术类似,此处不再赘述。值得注意的是,终端设备1100也并不是必须要包括图11中所示的所有部件,上述部件并不是必需的;此外,终端设备1100还可以包括图11中没有示出的部件,可以参考现有技术。
本申请实施例还提供一种计算机程序,其中当在网络设备中执行所述程序时,所述程序使得所述终端设备执行第一方面的实施例所述的信息指示方法。
本申请实施例还提供一种存储有计算机程序的存储介质,其中所述计算机程序使得网络设备执行第一方面的实施例所述的信息指示方法。
本申请实施例还提供一种计算机程序,其中当在终端设备中执行所述程序时,所述程序使得所述终端设备执行第二方面的实施例所述的信息接收方法。
本申请实施例还提供一种存储有计算机程序的存储介质,其中所述计算机程序使得终端设备执行第二方面的实施例所述的信息接收方法。
本申请以上的装置和方法可以由硬件实现,也可以由硬件结合软件实现。本申请涉及这样的计算机可读程序,当该程序被逻辑部件所执行时,能够使该逻辑部件实现上文所述的装置或构成部件,或使该逻辑部件实现上文所述的各种方法或步骤。本申请还涉及用于存储以上程序的存储介质,如硬盘、磁盘、光盘、DVD、flash存储器 等。
结合本申请实施例描述的方法/装置可直接体现为硬件、由处理器执行的软件模块或二者组合。例如,图中所示的功能框图中的一个或多个和/或功能框图的一个或多个组合,既可以对应于计算机程序流程的各个软件模块,亦可以对应于各个硬件模块。这些软件模块,可以分别对应于图中所示的各个步骤。这些硬件模块例如可利用现场可编程门阵列(FPGA)将这些软件模块固化而实现。
软件模块可以位于RAM存储器、闪存、ROM存储器、EPROM存储器、EEPROM存储器、寄存器、硬盘、移动磁盘、CD-ROM或者本领域已知的任何其它形式的存储介质。可以将一种存储介质耦接至处理器,从而使处理器能够从该存储介质读取信息,且可向该存储介质写入信息;或者该存储介质可以是处理器的组成部分。处理器和存储介质可以位于ASIC中。该软件模块可以存储在移动终端的存储器中,也可以存储在可插入移动终端的存储卡中。例如,若设备(如移动终端)采用的是较大容量的MEGA-SIM卡或者大容量的闪存装置,则该软件模块可存储在该MEGA-SIM卡或者大容量的闪存装置中。
针对附图中描述的功能方框中的一个或多个和/或功能方框的一个或多个组合,可以实现为用于执行本申请所描述功能的通用处理器、数字信号处理器(DSP)、专用集成电路(ASIC)、现场可编程门阵列(FPGA)或者其它可编程逻辑器件、分立门或者晶体管逻辑器件、分立硬件组件或者其任意适当组合。针对附图描述的功能方框中的一个或多个和/或功能方框的一个或多个组合,还可以实现为计算设备的组合,例如,DSP和微处理器的组合、多个微处理器、与DSP通信结合的一个或多个微处理器或者任何其它这种配置。
以上结合具体的实施方式对本申请进行了描述,但本领域技术人员应该清楚,这些描述都是示例性的,并不是对本申请保护范围的限制。本领域技术人员可以根据本申请的精神和原理对本申请做出各种变型和修改,这些变型和修改也在本申请的范围内。
关于包括以上实施例的实施方式,还公开下述的附记:
1.一种信息指示方法,应用于网络设备,所述信息指示方法包括:
所述网络设备改变服务模式;以及
所述网络设备向终端设备发送指示信息,其中,所述指示信息指示:
CSI测量方式更新;和/或,
CSI上报更新;和/或,
CSI-RS资源更新;和/或,
BWP切换。
2.根据附记1所述的方法,其中,所述服务模式包括正常模式和/或至少一种节能模式。
3.根据附记2所述的方法,其中,所述网络设备还发送配置信息给所述终端设备,其中,所示配置信息配置与所述至少一种节能模式中的一种节能模式相关的第一定时器;
其中,所述第一定时器设定所述至少一种节能模式中的一种节能模式的作用时间。
4.根据附记1-3任意一项所述的方法,其中,所述网络设备通过半静态信令或所述动态信令发送所述指示信息;其中,
所述半静态信令或所述动态信令为组信令,所述网络设备通过所述组信令向多个终端设备发送所述指示信息;或者
所述半静态信令或所述动态信令为用户设备特定信令,所述网络设备通过所述用户设备特定信令向一个终端设备发送所述指示信息。
5.根据附记4任意一项所述的方法,其中,所述网络设备通过指示CSI测量方式更新的所述指示信息和/或所述第一定时器指示CSI测量方式更改或者不更改。
6.根据附记5所述的方法,其中,在所述网络设备改变所述服务模式的情况下,指示所述CSI测量方式更新的所述指示信息通过一个或多个比特的一个取值指示更改所述CSI测量方式,和/或,通过所述一个或多个比特的另一个取值指示不更改所述CSI测量方式。
7.根据附记6所述的方法,其中,所述终端设备在所述第一定时器超时后更改所述CSI测量方式。
8.根据附记4所述的方法,其中,所述网络设备通过指示CSI上报更新的所述指示信息和/或所述第一定时器激活/去激活至少一个CSI上报。
9.根据附记8所述的方法,其中,在所述网络设备改变所述服务模式的情况下,指示CSI上报更新的所述指示信息指示激活第一CSI上报和/或去激活第二CSI上报,其中,所述第一CSI上报和/或所述第二CSI上报由高层信息配置。
10.根据附记9所述的方法,其中,所述终端设备挂起所述服务模式改变前的CSI上报;以及
所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的CSI上报。
11.根据附记8-10任意一项所述的方法,其中,所述第一CSI上报和/或所述第二CSI上报属于第一CSI上报列表,所述第一CSI上报列表包括CSI上报配置索引(CSI-ReportConfigId),其中,所述第一CSI上报列表和所述CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
12.根据附记8-11任意一项所述的方法,其中,所述第一CSI上报和/或所述第二CSI上报包括:周期性的CSI上报、半持续的CSI上报、或非周期性的CSI上报。
13.根据附记11任意一项所述的方法,其中,所述第一CSI上报列表包括的所述CSI上报配置索引(CSI-ReportConfigId)与以下至少一个信息的变更关联:
CSI上报周期以及偏移(offset);
CSI上报使用的资源;
CSI上报绑定的CSI-RS Resource的周期以及偏移(offset);或
CSI上报绑定的CSI-RS Resource的时频资源。
14.根据附记4所述的方法,其中,所述网络设备通过指示CSI-RS资源更新的所述指示信息和/或所述第一定时器激活/去激活至少一个CSI-RS资源。
15.根据附记14所述的方法,其中,在所述网络设备改变所述服务模式的情况下,指示CSI-RS资源更新的所述指示信息指示激活第一CSI-RS资源和/或去激活第二CSI-RS资源,其中,所述第一CSI-RS资源和/或所述二CSI-RS资源由高层信息配置;其中,所述第一CSI-RS资源和/或所述第二CSI-RS资源是相同的或是不同的。
16.根据附记14所述的方法,其中,所述终端设备挂起所述服务模式改变前的CSI-RS资源;以及
所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的CSI-RS资源。
17.根据附记14-16任意一项所述的方法,其中,所述第一CSI-RS资源和/或所述第二CSI-RS资源属于第一CSI-RS资源集合,
其中,所述第一CSI-RS资源集合包括CSI-RS资源(CSI-RS resource),和/或,CSI-RS端口(CSI-RS port);
其中,所述第一CSI-RS资源集合的索引以及所述第一CSI-RS资源集合包括的 CSI-RS资源(CSI-RS resource)的个数和索引,和/或,所述CSI-RS端口(CSI-RS port)的个数和/或索引由高层信息配置。
18.根据附记4所述的方法,其中,所述网络设备通过指示BWP切换的所述指示信息和/或所述第一定时器指示所述服务模式变更后的BWP。
19.根据附记18所述的方法,其中,在所述网络设备改变所述服务模式的情况下,指示BWP切换的所述指示信息指示所述服务模式变更后的BWP索引;其中,所述BWP索引由高层信息配置。
20.根据附记19所述的方法,其中,所述终端设备挂起所述服务模式改变前的BWP索引;以及
所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的BWP索引。
21.根据附记18-20任意一项所述的方法,其中,所述BWP索引与CSI上报配置索引(CSI-ReportConfigId)关联;其中,所述BWP索引关联的所述CSI上报配置索引(CSI-ReportConfigId)由高层信息配置。
22.根据附记21所述的方法,其中,在所述网络设备改变所述服务模式的情况下,切换至激活所述服务模式变更后的部分带宽(BWP)索引对应的BWP,同时激活关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报,去激活所述服务模式变更前的部分带宽(BWP)索引关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报。
23.根据附记1-21所述的方法,其中,在所述半静态信令或动态信令为组信令的情况下,所述指示信息为包括多个块的位图;其中每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置。
24.一种信息接收方法,应用于终端设备,所述信息接收方法包括:
所述终端设备接收指示信息;
所述终端设备根据所述指示信息确定:
CSI测量方式更新;和/或,
CSI上报更新;和/或,
CSI-RS资源更新;和/或,
BWP切换。
25.根据附记24所述的方法,其中,所述服务模式包括正常模式和/或至少一种 节能模式。
26.根据附记25所述的方法,其中,所述终端设备还接收配置信息,其中,所示配置信息配置与所述至少一种节能模式中的一种节能模式相关的第一定时器;
其中,所述第一定时器设定所述至少一种节能模式中的一种节能模式的作用时间。
27.根据附记24-26任意一项所述的方法,其中,所述终端设备通过半静态信令或动态信令接收所述指示信息;其中,
所述半静态信令或动态信令为组信令,所述网络设备通过所述组信令向多个终端设备发送所述指示信息;或者,
所述半静态信令或动态信令为用户设备特定信令,所述网络设备通过所述用户设备特定信令向一个终端设备发送所述指示信息。
28.一种终端设备,包括存储器和处理器,所述存储器存储有计算机程序,所述处理器被配置为执行所述计算机程序而实现如附记24至27任一项所述的数据调度方法。
29.一种网络设备,包括存储器和处理器,所述存储器存储有计算机程序,所述处理器被配置为执行所述计算机程序而实现如附记1至23任一项所述的数据发送方法。
Claims (20)
- 一种信息指示装置,应用于网络设备,其特征在于,所述装置包括:变更单元,其改变服务模式;发送单元,其向终端设备发送指示信息,其中,所述指示信息指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
- 根据权利要求1所述的装置,其中,所述服务模式包括正常模式和/或至少一种节能模式。
- 根据权利要求2所述的装置,其中,所述发送单元还发送配置信息给所述终端设备,其中,所述配置信息配置与所述至少一种节能模式中的一种节能模式相关的第一定时器;其中,所述第一定时器设定所述至少一种节能模式中的一种节能模式的作用时间。
- 根据权利要求3所述的装置,其中,所述发送单元通过半静态信令或动态信令发送所述指示信息;其中,所述半静态信令或所述动态信令为组信令,所述发送单元通过所述组信令向多个终端设备发送所述指示信息;或者所述半静态信令或所述动态信令为用户设备特定信令,所述发送单元通过所述用户设备特定信令向一个终端设备发送所述指示信息。
- 根据权利要求4所述的装置,其中,所述网络设备通过指示信道状态信息(CSI)测量方式更新的所述指示信息和/或所述第一定时器指示信道状态信息(CSI)测量方式更改或者不更改。
- 根据权利要求5所述的装置,其中,在所述变更单元改变所述服务模式的情况下,指示所述信道状态信息(CSI)测量方式更新的所述指示信息通过一个或多个比特的一个取值指示更改所述信道状态信息(CSI)测量方式,和/或,通过所述一个或多个比特的另一个取值指示不更改所述信道状态信息(CSI)测量方式;和/或,所述终端设备在所述第一定时器超时后更改所述信道状态信息(CSI)测量方式。
- 根据权利要求4所述的装置,其中,所述网络设备通过指示信道状态信息(CSI)上报更新的所述指示信息和/或所述第一定时器激活/去激活至少一个信道状态信息(CSI)上报。
- 根据权利要求7所述的装置,其中,在所述变更单元改变所述服务模式的情况下,指示信道状态信息(CSI)上报更新的所述指示信息指示激活第一信道状态信息(CSI)上报和/或去激活第二信道状态信息(CSI)上报,其中,所述第一信道状态信息(CSI)上报和/或所述第二信道状态信息(CSI)上报由高层信息配置;和/或,所述终端设备挂起所述服务模式改变前的信道状态信息(CSI)上报;以及所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的信道状态信息(CSI)上报。
- 根据权利要求8所述的装置,其中,所述第一信道状态信息(CSI)上报和/或所述第二信道状态信息(CSI)上报属于第一信道状态信息(CSI)上报列表,其中,所述第一信道状态信息(CSI)上报列表包括信道状态信息上报配置索引(CSI-ReportConfigId),其中,所述第一信道状态信息(CSI)上报列表和所述信道状态信息上报配置索引(CSI-ReportConfigId)由高层信息配置。
- 根据权利要求9所述的装置,其中,所述第一信道状态信息(CSI)上报列表包括的所述信道状态信息上报配置索引(CSI-ReportConfigId)与以下至少一个信息的变更关联:信道状态信息(CSI)上报周期以及偏移(offset);信道状态信息(CSI)上报使用的资源;信道状态信息(CSI)上报绑定的信道状态信息参考信号资源(CSI-RS resource)的周期以及偏移(offset);或信道状态信息(CSI)上报绑定的信道状态信息参考信号资源(CSI-RS resource)的时频资源。
- 根据权利要求4所述的装置,其中,所述网络设备通过指示信道状态信息参考信号(CSI-RS)资源更新的所述指示信息和/或所述第一定时器激活/去激活至少一个信道状态信息参考信号(CSI-RS)资源。
- 根据权利要求11所述的装置,其中,在所述变更单元改变所述服务模式的 情况下,指示信道状态信息参考信号(CSI-RS)资源更新的所述指示信息指示激活第一信道状态信息参考信号(CSI-RS)资源和/或去激活第二信道状态信息参考信号(CSI-RS)资源;其中,所述第一信道状态信息参考信号(CSI-RS)资源和/或所述二信道状态信息参考信号(CSI-RS)资源由高层信息配置;其中,所述第一信道状态信息参考信号(CSI-RS)资源和/或所述第二信道状态信息参考信号(CSI-RS)资源是相同的或是不同的;和/或,所述终端设备挂起所述服务模式改变前的信道状态信息参考信号(CSI-RS)资源;以及所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的信道状态信息参考信号(CSI-RS)资源。
- 根据权利要求12所述的装置,其中,所述第一信道状态信息参考信号(CSI-RS)资源和/或所述第二信道状态信息参考信号(CSI-RS)资源属于第一信道状态信息参考信号(CSI-RS)资源集合,其中,所述第一信道状态信息参考信号(CSI-RS)资源集合包括信道状态信息参考信号资源(CSI-RS resource),和/或,信道状态信息参考信号端口(CSI-RS port);其中,所述第一信道状态信息参考信号(CSI-RS)资源集合的索引以及所述第一信道状态信息参考信号(CSI-RS)资源集合包括的信道状态信息参考信号资源(CSI-RS resource)的个数和索引,和/或,所述信道状态信息参考信号端口(CSI-RS port)的个数和/或索引由高层信息配置。
- 根据权利要求4所述的装置,其中,所述变更单元通过指示部分带宽(BWP)切换的所述指示信息和/或所述第一定时器指示所述服务模式变更后的部分带宽(BWP)。
- 根据权利要求14所述的装置,其中,在所述变更单元改变所述服务模式的情况下,指示部分带宽(BWP)切换的所述指示信息指示所述服务模式变更后的部分带宽(BWP)索引;其中,所述部分带宽(BWP)索引由高层信息配置;和/或所述终端设备挂起所述服务模式改变前的部分带宽(BWP)索引;以及所述终端设备在所述第一定时器超时后恢复所述服务模式改变前的部分带宽(BWP)索引。
- 根据权利要求15所述的装置,其中,所述部分带宽(BWP)索引与信道状态信息上报配置索引(CSI-ReportConfigId)关联;其中,所述部分带宽(BWP)索引关联的所述信道状态信息上报配置索引(CSI-ReportConfigId)由高层信息配置。
- 根据权利要求16所述的装置,其中,在所述变更单元改变所述服务模式的情况下,切换至激活所述服务模式变更后的部分带宽(BWP)索引对应的部分带宽(BWP),同时激活关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报,去激活所述服务模式变更前的部分带宽(BWP)索引关联的信道状态信息上报配置索引(CSI-ReportConfigId)关联的信道状态信息(CSI)上报。
- 根据权利要求4所述的装置,其中,在所述半静态信令或所述动态信令为组信令的情况下,所述指示信息为包括多个块的位图;其中每个块对应一个终端设备,每个块的起始位置和/或大小由高层信令配置。
- 一种信息接收装置,应用于终端设备,其特征在于,所述装置包括:接收单元,其接收指示信息;确定单元,其根据所述指示信息确定:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换。
- 一种通信系统,包括:网络设备,其改变服务模式;以及所述网络设备向终端设备发送指示信息,其中,所述指示信息用于指示:信道状态信息(CSI)测量方式更新;和/或,信道状态信息(CSI)上报更新;和/或,信道状态信息参考信号(CSI-RS)资源更新;和/或,部分带宽(BWP)切换;所述终端设备,其接收所述指示信息。
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