WO2022135513A1 - 由用户设备执行的方法及用户设备 - Google Patents
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/02—Traffic management, e.g. flow control or congestion control
- H04W28/06—Optimizing the usage of the radio link, e.g. header compression, information sizing, discarding information
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- H—ELECTRICITY
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- H04W72/12—Wireless traffic scheduling
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/12—Wireless traffic scheduling
- H04W72/1263—Mapping of traffic onto schedule, e.g. scheduled allocation or multiplexing of flows
- H04W72/1268—Mapping of traffic onto schedule, e.g. scheduled allocation or multiplexing of flows of uplink data flows
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Definitions
- the present invention relates to the technical field of wireless communication, and more particularly, the present invention relates to a method performed by a user equipment and a corresponding user equipment.
- the UE entering the RRC inactive state can send a transmission block ( Transport Block).
- This transmission method may be referred to as PUR transmission.
- a transport block carrying user data may also be sent in message 3 or message A. Both of these transmission methods can be referred to as Small data transmission (SDT).
- DRB data radio bearer
- SDT small data transmission mode
- DRB for Non-SDT A data radio bearer that does not allow small data transmission
- the UE may have new data arriving in the process of performing small data transmission, and such data may need to be transmitted through DRB for non-SDT, or need to be transmitted through DRB for SDT.
- the UE can trigger a buffer status report (Buffer Status report, BSR).
- BSR Buffer Status report
- the present invention provides a method performed by a user equipment and a user equipment.
- a method executed by user equipment which is when the data of the data radio bearer DRB for Non SDT that is not based on small data transmission arrives in the process of small data transmission SDT by the user equipment UE.
- the control method includes the following steps:
- the UE is in the inactive state.
- the uplink data of a logical channel can be acquired by the MAC entity, and the DRB to which the logical channel belongs is not configured with SDT or the logical channel is not configured with SDT, the UE triggers the non-small data transmission buffer.
- the UE When there is a triggered Non SDT BSR and the UE has uplink resources, the UE instructs to generate a Non SDT BSR MAC CE, and starts the timer retx non SDT BSR-Timer, wherein, when the Non SDT BSR MAC CE is included in the transmitted MAC PDU, the UE cancels the triggered Non SDT BSR.
- Non SDT BSR MAC CE includes one or more of the following:
- the MAC subheader which carries a specific logical channel identifier LCID, is used to indicate the arrival of data of Non SDT;
- Logical channel identifier the logical channel is the logical channel to which the arriving uplink data belongs
- the logical channel group is the logical channel group to which the logical channel to which the arriving uplink data belongs;
- the buffer is the amount of available uplink data arriving in a logical channel, or the amount of all available uplink data in the logical channel group to which the logical channel belongs.
- the UE When the timer retx non SDT BSR-Timer runs out of time, if there is a logical channel that contains uplink data, and the logical channel is not configured with SDT, then the UE triggers the Non SDT BSR.
- the method further includes the following steps:
- the BSR is triggered based on the data arrival of the DRB for SDT;
- the UE When the UE has a triggered BSR and there are available uplink resources, the UE instructs to generate a BSR MAC CE, and starts or restarts the timer retxBSR-Timer, wherein, when the BSR MAC CE is included in the sent MAC PDU, The UE cancels the triggered BSR.
- the uplink data of a logical channel can be acquired by the MAC entity, and when the UE is in an inactive state, if the logical channel to which the data belongs is configured with SDT, and the priority of the logical channel is higher than other existing ones that can The priority of the logical channel of the acquired uplink data, then the UE triggers the BSR;
- the uplink data on a logical channel can be acquired by the MAC entity, and when the UE is in an inactive state, if the logical channel to which this data belongs is configured with SDT, and at this time, there are no other logical channels that can be acquired. Uplink data, then the UE triggers BSR.
- the UE When the UE is in an inactive state, if there is a logical channel that contains uplink data and the logical channel to which the data belongs is configured with SDT, the UE triggers BSR.
- the UE When the UE enters the connected state, if there is a running timer retx non SDT BSR-Timer, the UE stops the timer retx non SDT BSR-Timer.
- the UE When the UE enters the connected state, the UE resets the MAC layer, and the operation of resetting the MAC layer at least includes the operation of the UE to stop the running timer retx non SDT BSR-Timer.
- both Non SDT BSR MAC CE and regular BSR MAC CE need to be multiplexed in one MAC PDU, then the priority set to Non SDT BSR MAC CE is higher than the priority of regular BSR MAC CE class.
- a user equipment comprising:
- the above-mentioned instructions when executed by the above-mentioned processor, cause the above-mentioned user equipment to perform the method according to the above-mentioned description.
- the transmission delay can be shortened, and the signaling overhead can be saved.
- FIG. 1 is a flowchart showing a method executed by a user equipment according to an embodiment of the present invention.
- FIG. 2 is a schematic structural block diagram of the user equipment involved in the present invention.
- the NR mobile communication system and its subsequent evolved versions are used as an example application environment, and the base station and UE equipment supporting NR are used as examples to specifically describe various embodiments according to the present invention.
- the present invention is not limited to the following embodiments, but can be applied to more other wireless communication systems, such as eLTE, communication systems, or NB-Iot systems, or LTE-M systems. And it can be applied to other base stations and UE devices, such as base stations and UE devices supporting eLTE/NB-Iot/LTE-M.
- a UE entering an RRC inactive state can send a transport block (Transport Block) of a predetermined size and carrying data on a preconfigured uplink resource (preconfigured Uplink Resource, PUR).
- This transmission method may be referred to as PUR transmission.
- a transport block carrying user data may also be sent in message 3 or message A. Both of these transmission methods can be referred to as Small data transmission (SDT). Since such a transmission is always performed in an inactive state, such a transmission manner can also be referred to as data transmission of the UE in an inactive state.
- SDT Small data transmission
- DRB data radio bearer
- SDT data radio bearer based on small data transmission
- Such a DRB may also be referred to as an SDT-configured DRB.
- DRB data radio bearer that does not allow small data transmission
- DRB for Non-SDT (Data Radio Bearer Not Based on Small Data Transmission).
- DRB may also be referred to as a DRB without SDT configured.
- Each DRB corresponds to at least one logical channel (logical channel), and each logical channel has its own identity, also known as a logical channel identity (Logical channel Identity, LCID).
- logical channel identity also known as a logical channel identity (Logical channel Identity, LCID).
- the logical channel of a DRB configured with SDT can also be understood as a logical channel configured with SDT, or a logical channel that supports SDT (LC for SDT); a DRB that is not configured with SDT, its logical channel can also be It is understood as a logical channel that is not configured with SDT, or a logical channel that does not support SDT (LC for non-SDT)
- Data arrival means that the MAC entity (entity) can or can acquire uplink data.
- the MAC entity is responsible for assembling the uplink data into MAC PDUs.
- the data arriving here refers to the data that the MAC entity can acquire and use for assembly.
- the MAC entity obtains uplink data from one or more logical channels. Therefore, this situation can be understood as that data arrives on a certain logical channel, or the logical channel contains uplink data.
- Each logical channel is associated with a PDCP entity and an RLC entity, or a logical channel is associated with a DRB, and the DRB contains a corresponding PDCP entity and an RLC entity. How much data arrives needs to be calculated.
- the total data volume that can be obtained is calculated by considering the data volume of the PDCP layer and the RLC layer.
- the statistics are usually based on logical channels or logical channel groups. Counting the amount of data that can be obtained by a logical channel refers to counting the data volume of the PDCP layer and RLC layer related to the logical channel; when counting the amount of data that can be obtained by a logical channel group, it refers to counting all the logical channels belonging to the logical channel group. The sum of the amount of data that can be acquired by the channel.
- the UE can trigger BSR.
- the UE reports in units of logical channel groups (Logical Channel Groups, LCGs). If LC-1 and LC-2 belong to the same logical channel group, then according to the BSR, the base station cannot distinguish whether the reported data belongs to LC-1 or LC-2. That is, the arrival of data with DRB for non SDT cannot be recognized.
- the UE cannot report the arrival of the data of the DRB for Non SDT to the base station, resulting in a delay in data transmission.
- the UE when the UE is performing small data transmission and data of DRB for Non SDT arrives, the UE can retrigger an RRC resume (recovery) process. In this case, if the UE continues to report the arrival of DRB for Non SDT data to the base station through the BSR, it will become redundant.
- This embodiment provides a method for controlling the arrival of data with DRB for Non SDT when the UE performs small data transmission SDT.
- Non SDT BSR non-small data transfer cache status report
- the specific implementation can be, as shown in FIG. 1, including:
- Step S101 The UE is in an inactive state, when the uplink data of a certain logical channel can or can be acquired by the MAC entity (UL data becomes available to the MAC entity), and the DRB to which the logical channel belongs is not configured with SDT, or The logical channel is not configured with SDT, then the UE triggers the Non SDT BSR.
- Step S102 When there is a triggered Non SDT BSR, and when the UE has uplink resources (UL-SCH resources are available), the UE instructs to generate a Non SDT BSR MAC CE, and starts the timer retx non SDT BSR-Timer.
- the Non SDT BSR MAC CE is included in the transmitted MAC PDU, the UE cancels the triggered Non SDT BSR.
- the Non SDT BSR MAC CE here can contain one or more of the following:
- MAC subheader subheader carries a specific logical channel identifier LCID, which is used to indicate the arrival of Non SDT data, or to identify that the MAC CE is a Non SDT BSR MAC CE;
- the logical channel refers to the logical channel to which the arriving uplink data belongs, preferably, this logical channel is a logical channel that is not configured with SDT;
- the logical channel group refers to the logical channel group to which the logical channel to which the arriving uplink data belongs, preferably, this logical channel is a logical channel without SDT configured, and preferably, belongs to this logical channel
- the logical channels of the group are all logical channels that are not configured with SDT, or the logical channel group does not contain logical channels configured with SDT;
- each buffer size corresponds to or is associated with a logical channel or logical channel group.
- the UE when the timer retx non SDT BSR-Timer runs overtime, if at least one logical channel contains uplink data, and the logical channel is not configured with SDT, then the UE will trigger the non SDT BSR.
- Containing uplink data here may refer to the arrival of uplink data as described above. Since there is a triggered non-SDT BSR, the UE may perform the operation in step S102.
- the timer retx non SDT BSR-Timer runs out, if no logical channel containing uplink data is configured with SDT, then the UE will not trigger the non SDT BSR.
- the BSR is triggered according to the arrival of the DRB for SDT data, that is, the DRB for The arrival of non SDT data will not trigger BSR.
- the UE can trigger the BSR.
- the uplink data on a certain logical channel can be acquired by the MAC entity, and when the UE is in an inactive state, if the logical channel to which this data belongs is configured with SDT, and at this time, there are no other logical channels that can be acquired. , the UE can trigger BSR.
- the "other" logical channel herein refers to a logical channel configured with SDT.
- the UE can instruct to generate a BSR MAC CE (instruct to generate the BSR), and start or restart the timer retxBSR-Timer.
- the timer retxBSR-Timer can be restarted.
- the triggered BSR will be cancelled (cancel)
- the UE when the timer retxBSR-Timer expires (expiry) and the UE is in an inactive state, if there is a logical channel that contains uplink data and the logical channel to which the data belongs is configured with SDT, the UE will trigger BSR.
- the UE can trigger the BSR under the following conditions:
- the uplink data of a logical channel can or can be acquired by the MAC entity (UL data becomes available to the MAC entity), and when the UE is in the connected state, if the priority of the logical channel to which this data belongs is higher than other If there is a priority of the logical channel of the available uplink data, the UE can trigger the BSR
- the UE can trigger the BSR.
- the UE When the UE is in the connected state, if there is a logical channel containing uplink data, the UE will trigger BSR.
- the second embodiment can be used as a supplement to the first embodiment, or can be implemented independently.
- the BSR triggered here may be called regular BSR, and the BSR MAC CE generated based on the triggered BSR may be called regular BSR MAC CE, to distinguish it from the Non SDT BSR MAC CE in the first embodiment.
- the UE when the UE enters the connected state, if there is a running retx non SDT BSR-Timer, the UE stops the retx non SDT BSR-Timer.
- the UE's decision to enter the connected state may be based on the state of the upper layer, for example, the state of the RRC layer, or the RRC layer instructs the MAC layer UE to enter the connected state. .
- the UE When the UE enters the connected state, the UE resets the MAC layer.
- the operation of resetting the MAC layer includes at least the UE stopping the running retx non SDT BSR-Timer.
- the UE may reset the MAC layer after receiving the RRC resume message (RRC resume message).
- RRC resume message is an RRC resume request message (RRC) sent to the UE for small data transmission (SDT).
- RRC RRC resume request message
- SDT small data transmission
- resume request message is the response message to the RRC resume request message sent by the UE and triggered by the SDT.
- Non SDT BSR MAC CE and regular BSR MAC CE need to be multiplexed and assembled in one MAC PDU, then Non SDT BSR MAC CE CE has higher priority than regular BSR MAC CE.
- the "priority" here means that in the case of a certain resource, the Non SDT BSR MAC CE is given priority to be put into the MAC PDU, and if there are remaining resources, the regular BSR MAC CE will continue to be considered.
- Priority refers to prioritizing multiplexing or prioritizing assemble in a multiplexing assembly operation.
- the UE when the UE enters the connected state, if there is a triggered BSR, whether it is the Non SDT BSR mentioned in the first embodiment or the regular BSR mentioned in the second embodiment, the UE cancels the Triggered BSR.
- the UE's decision to enter the connected state may be based on the state of the upper layer, for example, the state of the RRC layer, or the RRC layer instructs the MAC layer UE to enter the connected state.
- the UE When the UE enters the connected state, the UE resets the MAC layer.
- the operation of resetting the MAC layer includes at least cancelling the triggered BSR (Non SDT BSR or regular BSR).
- the UE may reset the MAC layer after receiving the RRC resume message (RRC resume message).
- RRC resume message is an RRC resume request message (RRC) sent to the UE for small data transmission (SDT).
- RRC RRC resume request message
- SDT small data transmission
- resume request message is the response message to the RRC resume request message sent by the UE and triggered by the SDT.
- FIG. 2 is a schematic structural block diagram of the user equipment involved in the present invention.
- the user equipment UE200 includes a processor 201 and a memory 202 .
- the processor 201 may include, for example, a microprocessor, a microcontroller, an embedded processor, or the like.
- the memory 202 may include, for example, volatile memory (eg, random access memory RAM), a hard disk drive (HDD), non-volatile memory (eg, flash memory), or other memory, or the like.
- Program instructions are stored on the memory 202 . When the instruction is executed by the processor 201, the above method described in detail in the present invention and executed by the user equipment can be executed.
- a program running on a device may be a program that causes a computer to implement the functions of the embodiments of the present invention by controlling a central processing unit (CPU).
- the program or information processed by the program may be temporarily stored in volatile memory (eg, random access memory RAM), a hard disk drive (HDD), non-volatile memory (eg, flash memory), or other memory systems.
- a program for realizing the functions of the embodiments of the present invention can be recorded on a computer-readable recording medium.
- the corresponding functions can be realized by causing a computer system to read programs recorded on the recording medium and execute the programs.
- the so-called "computer system” here may be a computer system embedded in the device, and may include an operating system or hardware (eg, peripheral devices).
- the "computer-readable recording medium” may be a semiconductor recording medium, an optical recording medium, a magnetic recording medium, a recording medium that dynamically stores a program for a short period of time, or any other recording medium readable by a computer.
- circuits eg, monolithic or multi-chip integrated circuits.
- Circuits designed to perform the functions described in this specification may include general purpose processors, digital signal processors (DSPs), application specific integrated circuits (ASICs), field programmable gate arrays (FPGAs), or other programmable logic devices, discrete gate or transistor logic, discrete hardware components, or any combination of the above.
- DSPs digital signal processors
- ASICs application specific integrated circuits
- FPGAs field programmable gate arrays
- a general-purpose processor may be a microprocessor or any existing processor, controller, microcontroller, or state machine.
- the above circuit may be a digital circuit or an analog circuit. In the event that new integrated circuit technologies emerge as a result of advances in semiconductor technology that replace existing integrated circuits, one or more embodiments of the present invention may also be implemented using these new integrated circuit technologies.
- the present invention is not limited to the above-described embodiments. Although various examples of the described embodiments have been described, the invention is not limited thereto.
- Fixed or non-mobile electronic equipment installed indoors or outdoors can be used as terminal equipment or communication equipment, such as AV equipment, kitchen equipment, cleaning equipment, air conditioners, office equipment, vending machines, and other household appliances.
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Abstract
本发明提供一种由用户设备执行的方法及用户设备,该方法是UE在进行SDT的过程中有DRB for Non SDT的数据到达时的控制方法,包括如下步骤:UE处于非激活态,当某个逻辑信道的上行数据能够被MAC实体获取时,并且该逻辑信道所属的DRB没有被配置SDT或者是该逻辑信道没有被配置SDT,那么UE触发Non SDT BSR;当存在被触发的Non SDT BSR时以及UE有上行资源时,UE指示生成Non SDT BSR MAC CE,并且启动定时器,其中,当Non SDT BSR MAC CE被包含在发送的MAC PDU中时,UE取消触发的Non SDT BSR。
Description
本发明涉及无线通信技术领域,更具体地,本发明涉及由用户设备执行的方法以及相应的用户设备。
为了缩短传输时延,以及节约信令开销,进入RRC非激活态(RRC INACTIVE STATE)的UE可以在预先配置的上行资源(preconfigured Uplink Resource,PUR)上发送既定大小的、携带数据的传输块(Transport Block)。这种传输方式可以称为PUR传输。还可以在随机接入的过程中,在消息三或者消息A中发送携带用户数据的传输块。这两种传输方式都可以被称为小数据传输(Small data transmission,SDT)。
可以采用小数据传输方式进行传输的数据无线承载(Data radio Bearer,DRB)被称DRB for SDT。不允许采用小数据传输方式进行传输的数据无线承载被称为DRB for Non-SDT。UE在执行小数据传输的过程中可以有新的数据到达,这样的数据可以是需要经由DRB for non-SDT进行传输的,或者是需要经由DRB for SDT进行传输的。
在现有技术中,当某个逻辑信道的上行数据能够被MAC实体获取时,UE可以触发缓存状态报告(Buffer Status report,BSR)。当这个逻辑信道对应的DRB被配置了SDT或者没有被配置SDT,UE需要如何触发生成BSR,是需要解决的问题。
发明内容
为了解决现有技术中的上述问题,本发明提供了一种由用户设备执行的方法以及用户设备。
根据本发明的一个方面,提供了一种由用户设备执行的方法,是用户设备UE在进行小数据传输SDT的过程中有不基于小数据传输的数据 无线承载DRB for Non SDT的数据到达时的控制方法,包括如下步骤:
UE处于非激活态,当某个逻辑信道的上行数据能够被MAC实体获取时,并且该逻辑信道所属的DRB没有被配置SDT或者是该逻辑信道没有被配置SDT,那么UE触发非小数据传输缓存状态报告Non SDT BSR;
当存在被触发的Non SDT BSR时以及UE有上行资源时,UE指示生成Non SDT BSR MAC CE,并且启动定时器retx non SDT BSR-Timer,其中,当Non SDT BSR MAC CE被包含在发送的MAC PDU中时,UE取消触发的Non SDT BSR。
在上述的由用户设备执行的方法中,优选的是,
上述Non SDT BSR MAC CE包含下述的一项或者多项:
MAC子头,该子头中携带着特定的逻辑信道标识LCID,用于指示Non SDT的数据到达;
逻辑信道标识,该逻辑信道是到达的上行数据所属的逻辑信道;
逻辑信道组标识,该逻辑信道组是到达的上行数据所属的逻辑信道所属的逻辑信道组;
缓存大小,该缓存是一个逻辑信道中到达的能够获取的上行数据量,或者是该逻辑信道所属的逻辑信道组中的所有能够获取的上行数据量。
在上述的由用户设备执行的方法中,优选的是,
当定时器retx non SDT BSR-Timer运行超时时,如果有逻辑信道包含了上行数据,并且该逻辑信道没有被配置SDT,那么UE触发Non SDT BSR。
在上述的由用户设备执行的方法中,优选的是,还包括如下步骤:
在UE进行小数据传输的过程中,基于DRB for SDT的数据到达来触发BSR;
当UE存在被触发的BSR时以及有可用的上行资源时,UE指示生成BSR MAC CE,并且启动或者重新启动定时器retxBSR-Timer,其中,当BSR MAC CE被包含在发送的MAC PDU中时,UE取消触发的BSR。
在上述的由用户设备执行的方法中,优选的是,
当某个逻辑信道的上行数据能够被MAC实体获取时,并且当UE 处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,以及该逻辑信道的优先级高于其他已有的能够获取的上行数据的逻辑信道的优先级,那么UE触发BSR;
当某个逻辑信道上的上行数据能够被MAC实体获取时,并且当UE处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,并且,此时没有其他的逻辑信道包含能够获取的上行数据,那么UE触发BSR。
在上述的由用户设备执行的方法中,优选的是,
当定时器retxBSR-Timer运行超时时,
当UE处于非激活态时,如果有逻辑信道包含了上行数据并且这个数据所属的逻辑信道被配置了SDT,那么UE触发BSR。
在上述的由用户设备执行的方法中,优选的是,
当UE进入连接态时,如果有正在运行的定时器retx non SDT BSR-Timer,那么UE停止该定时器retx non SDT BSR-Timer。
在上述的由用户设备执行的方法中,优选的是,
当UE进入连接态时,UE重置MAC层,在重置MAC层的操作中至少包括了UE停止正在运行的定时器retx non SDT BSR-Timer的操作。
在上述的由用户设备执行的方法中,优选的是,
如果UE在生成MAC PDU时,同时存在Non SDT BSR MAC CE以及regular BSR MAC CE需要复用在一个MAC PDU的情况下,那么设置为Non SDT BSR MAC CE的优先级高于regular BSR MAC CE的优先级。
根据本发明的另一个方面,提供了一种用户设备,包括:
处理器;以及
存储器,上述存储器上存储有指令,
上述指令在由上述处理器运行时,使上述用户设备执行根据上文所描述的方法。
根据本发明所涉及的由用户设备执行的方法以及相应的用户设备,能够缩短传输时延,以及节约信令开销。
通过下文结合附图的详细描述,本发明的上述和其它特征将会变得更加明显,其中:
图1是表示本发明的一实施例涉及的由用户设备执行的方法的流程图。
图2是本发明涉及的用户设备的简要结构框图。
下面结合附图和具体实施方式对本发明进行详细阐述。应当注意,本发明不应局限于下文所述的具体实施方式。另外,为了简便起见,省略了对与本发明没有直接关联的公知技术的详细描述,以防止对本发明的理解造成混淆。
在具体描述之前,先对本发明中提到的若干术语做如下说明。除非另有指出,本发明中涉及的术语都具有下文的含义。
UE User Equipment用户设备
NR New Radio新一代无线技术
LTE Long Term Evolution长期演进技术
eLTE Enhaced Long Term Evolution增强的长期演进技术
RRC Radio Resource Control无线资源控制(层)
MAC Medium Access Control媒体接入控制(层)
MAC CE MAC Control Element MAC控制元素
MAC PDU MAC Protocol Data Unit MAC协议数据单元
PUSCH Physical Uplink Shared Channel物理上行共享信道
PDCCH Physical Downlink Control Channel物理下行控制信道
SDAP Service Data Adaptation Protocol业务数据自适应层协议
PDCP Packet Data Convergence Protocol分组数据汇聚协议
RLC Radio Link Control,无线链路层控制协议
BSR Buffer Status Report缓存状态报告
DRB Data Radio Bearer数据无线承载
SDT Small Data Transmission小数据传输
UL-SCH Uplink Shared Channel上行共享信道
下文以NR移动通信系统及其后续的演进版本作为示例应用环境,以支持NR的基站和UE设备为例,具体描述了根据本发明的多个实施方式。然而,需要指出的是,本发明不限于以下实施方式,而是可适用于更多其它的无线通信系统,例如eLTE,通信系统,或者是NB-Iot系统,又或者是LTE-M系统。而且可以适用于其他基站和UE设备,例如支持eLTE/NB-Iot/LTE-M的基站和UE设备。
进入RRC非激活态(RRC INACTIVE STATE)的UE可以在预先配置的上行资源(preconfigured Uplink Resource,PUR)上发送既定大小的、携带数据的传输块(Transport Block)。这种传输方式可以称为PUR传输。还可以在随机接入的过程中,在消息三或者消息A中发送携带用户数据的传输块。这两种传输方式都可以被称为小数据传输(Small data transmission,SDT)。由于这样的传输总是在非激活态下进行,因此这样的传输方式也可以被称为UE在非激活态下的数据传输。
可以采用小数据传输方式进行传输的数据无线承载(Data radio Bearer,DRB)被称DRB for SDT(基于小数据传输的数据无线承载)。这样的DRB还可以被称为是被配置了SDT的DRB。
不允许采用小数据传输方式进行传输的数据无线承载被称为DRB for Non-SDT(不基于小数据传输的数据无线承载)。这样的DRB还可以被称为是没有被配置SDT的DRB。
每一个DRB对应至少一个逻辑信道(logical channel),每个逻辑信道有自己的标识,又称为逻辑信道标识(Logical channel Identity,LCID)。
对应的,被配置了SDT的DRB,其逻辑信道也可以理解为被配置了SDT的逻辑信道,或者是支持SDT的逻辑信道(LC for SDT);没有被配置SDT的DRB,其逻辑信道也可以理解为没有被配置SDT的逻辑信道,或者是不支持SDT的逻辑信道(LC for non-SDT)
数据到达
数据到达是指MAC实体(entity)可以或者能够获取上行数据。在UE内部,MAC实体负责将上行数据组装成MAC PDU。这里到达的数据是指MAC实体可以获取并用于组装的数据。MAC实体从一个或者多个逻辑信道获取上行数据。因此,这种情况可以理解为针对对某个逻辑 信道有数据到达,或者是该逻辑信道包含了上行数据。每个逻辑信道和一个PDCP实体以及RLC实体相关联,或者说一个逻辑信道是和一个DRB相关联,而在这个DRB中包含着对应的PDCP实体以及RLC实体。有多少数据到达是需要计算的。通常是考虑了PDCP层,RLC层的数据量而计算出的可以获取的总的数据量。在统计的时候通常以逻辑信道或者逻辑信道组为单位。统计一个逻辑信道可以获取的数据量是指统计与该逻辑信道相关的PDCP层以及RLC层的数据量;统计一个逻辑信道组可以获取的数据量时,是指统计所有属于该逻辑信道组的逻辑信道可以获取的的数据量的总和。
UE在执行小数据传输的过程中,仅有DRB for SDT上的上行数据才可以被发送。但是,在传输的过程中,可以有需要经由DRB for SDT进行传输的数据到达,还可以有需要经由DRB for non-SDT进行传输的数据到达。
在有DRB for Non SDT的数据到达时,
-当该数据所属的逻辑信道(假设LC-1)的优先级高于DRB forSDT中的数据所属的逻辑信道(假设LC-2)的优先级,那么UE可以触发BSR。但是在现有BSR的设计中,UE是以逻辑信道组(Logical Channel Group,LCG)为单位进行报告的。如果LC-1和LC-2属于相同的逻辑信道组,那么根据BSR,基站不能区分报告的数据是属于LC-1还是LC-2的。即不能识别有DRB for non SDT的数据到达。
-当LC-1的优先级低于LC-2时,UE不会触发BSR。
可见,在上述情况下,UE无法将DRB for Non SDT的数据到达情况向基站汇报,从而导致了数据传输的延时。
此外,当UE在执行小数据传输的过程中,有DRB for Non SDT的数据到达,UE可以重新触发一个RRC resume(恢复)过程。在这种情况下,如果UE继续通过BSR向基站报告DRB for Non SDT的数据到达,将变得冗余。
为了解决背景技术中提到的问题,以下,详细描述本发明的若干实施例。
实施例一
本实施例给出了一种UE在进行小数据传输SDT的过程中有DRB for Non SDT的数据到达时的控制方法。
为了避免DRB for Non SDT(不基于小数据传输的数据无线承载)的数据传输延迟,在UE进行小数据传输的过程中,如果有DRB for Non SDT的数据到达时,可以触发一个Non SDT BSR(非小数据传输缓存状态报告)。
具体的实施方式可以是,如图1所示,包括:
步骤S101:UE处于非激活态,当某个逻辑信道的上行数据可以或者能够被MAC实体获取(UL data becomes available to the MAC entity)时,并且该逻辑信道所属的DRB没有被配置SDT,或者是该逻辑信道没有被配置SDT,那么UE触发Non SDT BSR。
步骤S102:当存在被触发的Non SDT BSR时,以及UE有上行资源(UL-SCH resources are available)时,UE指示生成Non SDT BSR MAC CE,并且启动定时器retx non SDT BSR-Timer。当Non SDT BSR MAC CE被包含在发送的MAC PDU中,UE取消触发的Non SDT BSR。
这里的Non SDT BSR MAC CE可以包含下述的一项或者多项:
-包含一个MAC子头subheader,该子头中携带着特定的逻辑信道标识LCID,用于指示Non SDT的数据到达,或者标识该MAC CE是Non SDT BSR MAC CE;
-包含逻辑信道标识,该逻辑信道是指到达的上行数据所属的逻辑信道,优选的,这个逻辑信道是没有被配置SDT的逻辑信道;
-包含逻辑信道组标识,该逻辑信道组是指到达的上行数据所属的逻辑信道所属的逻辑信道组,优选的,这个逻辑信道是没有被配置SDT的逻辑信道,以及优选的,属于这个逻辑信道组的逻辑信道都是没有被配置SDT的逻辑信道,或者是这个逻辑信道组不包含被配置了SDT的逻辑信道;
-包含缓存大小(buffer size),这里是buffer是指一个逻辑信道中 到达的、可以获取的上行数据量(the amount of data available),或者是该逻辑信道所属的逻辑信道组中的所有可以获取的上行数据量。优选的,每一个buffer size和一个逻辑信道或者逻辑信道组对应或者相关联。
优选的,当定时器retx non SDT BSR-Timer运行超时时,如果至少有一个逻辑信道包含(contain)了上行数据,并且该逻辑信道没有被配置SDT,那么UE会触发non SDT BSR。这里的“包含上行数据”可以指的是前文所述的有上行数据到达。由于存在触发的non SDT BSR,UE可以执行步骤S102中的操作。当定时器retx non SDT BSR-Timer运行超时时,如果没有一个包含了上行数据的逻辑信道被配置了SDT,那么UE不会触发non SDT BSR。
实施例二
为了避免DRB for Non SDT的数据被冗余报告,在UE进行小数据传输的过程中(即UE处于非连接态下进行数据传输时),根据DRB for SDT的数据到达来触发BSR,即DRB for non SDT的数据到达将不触发BSR。
具体的实施方式可以是
-当某个逻辑信道的上行数据可以被MAC实体获取(UL data becomes available to the MAC entity)时,并且当UE处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,以及该逻辑信道的优先级高于其他已有可获取的上行数据的逻辑信道的优先级,那么UE可以触发BSR。
-当某个逻辑信道上的上行数据可以被MAC实体获取时,并且当UE处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,并且,此时没有其他的逻辑信道包含可获取的上行数据,那么UE可以触发BSR。优选的这里“其他”的逻辑信道是指被配置了SDT的逻辑信道。
优选的,当UE存在被触发的BSR时,以及有可用的上行资源时,UE可以指示生成BSR MAC CE(instruct to generate the BSR),并且启动或者重新启动定时器retxBSR-Timer。
优选的,当UE有可用的上行资源时,可以重新启动定时器retxBSR-Timer。
优选的,一旦该BSR MAC CE被包含在发送的MAC PDU中,这个触发的BSR就会被取消(cancel)
优选的,当定时器retxBSR-Timer运行超时(expiry)时,以及UE处于非激活态时,如果有逻辑信道包含了上行数据并且这个数据所属的逻辑信道被配置了SDT,那么UE会触发BSR。
可选的,作为上述UE在进行小数据传输的过程中的方案的补充,即UE在采用非小数据传输的数据传输过程中,可以在下述情况下触发BSR:
-当某个逻辑信道的上行数据可以或者能够被MAC实体获取时(UL data becomes available to the MAC entity),并且当UE处于连接态时,如果这个数据所属的逻辑信道的优先级高于其他已有的可获取的上行数据的逻辑信道的优先级,那么UE可以触发BSR
-当某个逻辑信道上的上行数据可以被MAC实体获取时,并且当UE处于连接态时,如果此时没有其他的逻辑信道包含可获取的上行数据,那么UE可以触发BSR。
以及
当定时器retxBSR-Timer运行超时时,
-当UE处于连接态时,如果有逻辑信道包含了上行数据,那么UE会触发BSR。
实施例二可以作为实施例一的补充,或者是单独实施。这里被触发的BSR可以被称为regular BSR,以及基于该触发的BSR而生成的BSR MAC CE可以被称regular BSR MAC CE,以和实施例一中的Non SDT BSR MAC CE进行区分。
实施例三
在前述实施例的基础上,当UE进入连接态时,如果有正在运行的retx non SDT BSR-Timer,UE停止该retx non SDT BSR-Timer。
这里UE对进入连接态的判断可以基于上层的状态,例如RRC层的状态,或者是RRC层指示MAC层UE进入连接态。。
上述方案的又一实施方式可以是
当UE进入连接态时,UE重置MAC层。在重置MAC层的操作中至少包括了UE停止正在运行的retx non SDT BSR-Timer。
UE可以在接收到RRC恢复消息(RRC resume message)之后重置MAC层,优选的,这个接收到的RRC resume消息是对UE发送的、用于小数据传输(SDT)的RRC恢复请求消息(RRC resume requestmessage)的响应消息,或者等价的,是对于UE发送的、由SDT触发的RRC resume request消息的响应消息。
实施例四
在前述实施例的基础上,如果UE在生成MAC PDU时,同时存在Non SDT BSR MAC CE以及regular BSR MAC CE需要复用组装(multiplex and assemble)在一个MAC PDU的情况下,那么Non SDT BSR MAC CE的优先级高于regular BSR MAC CE。这里的“优先”是指在资源一定的情况下,优先考虑将Non SDT BSR MAC CE放入MAC PDU,如果资源还有剩余,再继续考虑regular BSR MAC CE。这样的“优先”是指在复用组装操作中的优先复用(multiplex)或者优先组装(assemble)。
实施例五
在前述实施例的基础上,当UE进入连接态时,如果存在有被触发的BSR,无论是实施例一中提到的Non SDT BSR或者还是实施例二中提到的regular BSR,那么UE取消触发的BSR。
这里UE对进入连接态的判断可以基于上层的状态,例如RRC层的状态,或者是RRC层指示MAC层UE进入连接态。
上述方案的又一实施方式可以是
当UE进入连接态时,UE重置MAC层。在重置MAC层的操作中至少包括了取消被触发的BSR(Non SDT BSR或者regular BSR)。
UE可以在接收到RRC恢复消息(RRC resume message)之后重置 MAC层,优选的,这个接收到的RRC resume消息是对UE发送的、用于小数据传输(SDT)的RRC恢复请求消息(RRC resume requestmessage)的响应消息,或者等价的,是对于UE发送的、由SDT触发的RRC resume request消息的响应消息。
图2是本发明涉及的用户设备的简要结构框图。如图2所示,该用户设备UE200包括处理器201和存储器202。处理器201例如可以包括微处理器、微控制器、嵌入式处理器等。存储器202例如可以包括易失性存储器(如随机存取存储器RAM)、硬盘驱动器(HDD)、非易失性存储器(如闪速存储器)、或其他存储器等。存储器202上存储有程序指令。该指令在由处理器201运行时,可以执行本发明详细描述的由用户设备执行的上述方法。
运行在根据本发明的设备上的程序可以是通过控制中央处理单元(CPU)来使计算机实现本发明的实施例功能的程序。该程序或由该程序处理的信息可以临时存储在易失性存储器(如随机存取存储器RAM)、硬盘驱动器(HDD)、非易失性存储器(如闪速存储器)、或其他存储器系统中。
用于实现本发明各实施例功能的程序可以记录在计算机可读记录介质上。可以通过使计算机系统读取记录在所述记录介质上的程序并执行这些程序来实现相应的功能。此处的所谓“计算机系统”可以是嵌入在该设备中的计算机系统,可以包括操作系统或硬件(如外围设备)。“计算机可读记录介质”可以是半导体记录介质、光学记录介质、磁性记录介质、短时动态存储程序的记录介质、或计算机可读的任何其他记录介质。
用在上述实施例中的设备的各种特征或功能模块可以通过电路(例如,单片或多片集成电路)来实现或执行。设计用于执行本说明书所描述的功能的电路可以包括通用处理器、数字信号处理器(DSP)、专用集成电路(ASIC)、现场可编程门阵列(FPGA)、或其他可编程逻辑器件、分立的门或晶体管逻辑、分立的硬件组件、或上述器件的任意组合。通用处理器可以是微处理器,也可以是任何现有的处理器、控制器、微控 制器、或状态机。上述电路可以是数字电路,也可以是模拟电路。因半导体技术的进步而出现了替代现有集成电路的新的集成电路技术的情况下,本发明的一个或多个实施例也可以使用这些新的集成电路技术来实现。
此外,本发明并不局限于上述实施例。尽管已经描述了所述实施例的各种示例,但本发明并不局限于此。安装在室内或室外的固定或非移动电子设备可以用作终端设备或通信设备,如AV设备、厨房设备、清洁设备、空调、办公设备、自动贩售机、以及其他家用电器等。
如上,已经参考附图对本发明的实施例进行了详细描述。但是,具体的结构并不局限于上述实施例,本发明也包括不偏离本发明主旨的任何设计改动。另外,可以在权利要求的范围内对本发明进行多种改动,通过适当地组合不同实施例所公开的技术手段所得到的实施例也包含在本发明的技术范围内。此外,上述实施例中所描述的具有相同效果的组件可以相互替代。
Claims (10)
- 一种由用户设备执行的方法,是用户设备UE在进行小数据传输SDT的过程中有不基于小数据传输的数据无线承载DRB for Non SDT的数据到达时的控制方法,包括如下步骤:UE处于非激活态,当某个逻辑信道的上行数据能够被MAC实体获取时,并且该逻辑信道所属的DRB没有被配置SDT或者是该逻辑信道没有被配置SDT,那么UE触发非小数据传输缓存状态报告Non SDT BSR;当存在被触发的Non SDT BSR时以及UE有上行资源时,UE指示生成Non SDT BSR MAC CE,并且启动定时器retx non SDT BSR-Timer,其中,当Non SDT BSR MAC CE被包含在发送的MAC PDU中时,UE取消触发的Non SDT BSR。
- 根据权利要求1所述的由用户设备执行的方法,其中,上述Non SDT BSR MAC CE包含下述的一项或者多项:MAC子头,该子头中携带着特定的逻辑信道标识LCID,用于指示Non SDT的数据到达;逻辑信道标识,该逻辑信道是到达的上行数据所属的逻辑信道;逻辑信道组标识,该逻辑信道组是到达的上行数据所属的逻辑信道所属的逻辑信道组;缓存大小,该缓存是一个逻辑信道中到达的能够获取的上行数据量,或者是该逻辑信道所属的逻辑信道组中的所有能够获取的上行数据量。
- 根据权利要求1所述的由用户设备执行的方法,其中,当定时器retx non SDT BSR-Timer运行超时时,如果有逻辑信道包含了上行数据,并且该逻辑信道没有被配置SDT,那么UE触发Non SDT BSR。
- 根据权利要求1所述的由用户设备执行的方法,其中,还包括如下步骤:在UE进行小数据传输的过程中,根据DRB for SDT的数据到达触发BSR;当UE存在被触发的BSR时以及有可用的上行资源时,UE指示生成BSR MAC CE,并且启动或者重新启动定时器retxBSR-Timer,其中,当BSR MAC CE被包含在发送的MAC PDU中时,UE取消触发的BSR。
- 根据权利要求4所述的由用户设备执行的方法,其中,当某个逻辑信道的上行数据能够被MAC实体获取时,并且当UE处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,以及该逻辑信道的优先级高于其他已有的能够获取的上行数据的逻辑信道的优先级,那么UE触发BSR;当某个逻辑信道上的上行数据能够被MAC实体获取时,并且当UE处于非激活态时,如果这个数据所属的逻辑信道被配置了SDT,并且,此时没有其他的逻辑信道包含能够获取的上行数据,那么UE触发BSR。
- 根据权利要求4所述的由用户设备执行的方法,其中,当定时器retxBSR-Timer运行超时时,当UE处于非激活态时,如果有逻辑信道包含了上行数据并且这个数据所属的逻辑信道被配置了SDT,那么UE触发BSR。
- 根据权利要求1-3中任一项所述的由用户设备执行的方法,其中,当UE进入连接态时,如果有正在运行的定时器retx non SDT BSR-Timer,那么UE停止该定时器retx non SDT BSR-Timer。
- 根据权利要求1-3中任一项所述的由用户设备执行的方法,其中,当UE进入连接态时,UE重置MAC层,在重置MAC层的操作中至少包括了UE停止正在运行的定时器retx non SDT BSR-Timer的操作。
- 根据权利要求4所述的由用户设备执行的方法,其中,如果UE在生成MAC PDU时,同时存在Non SDT BSR MAC CE以及regular BSR MAC CE需要复用在一个MAC PDU的情况下,那么设置为Non SDT BSR MAC CE的优先级高于regular BSR MAC CE的优先级。
- 一种用户设备,包括:处理器;以及存储器,上述存储器上存储有指令,上述指令在由上述处理器运行时,使上述用户设备执行根据权利要 求1-9中任一项所述的方法。
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