WO2011126311A2 - 이동통신 시스템에서 스케줄링 정보를 처리하는 방법 및 장치 - Google Patents
이동통신 시스템에서 스케줄링 정보를 처리하는 방법 및 장치 Download PDFInfo
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- H04W72/0446—Resources in time domain, e.g. slots or frames
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- H04W72/23—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal
- H04W72/231—Control channels or signalling for resource management in the downlink direction of a wireless link, i.e. towards a terminal the control data signalling from the layers above the physical layer, e.g. RRC or MAC-CE signalling
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Definitions
- the present invention relates to a method and apparatus for processing scheduling information by a terminal in which a plurality of forward and reverse carriers are integrated in a mobile communication system.
- a mobile communication system has been developed for the purpose of providing communication while securing user mobility.
- Such a mobile communication system has reached a stage capable of providing high-speed data communication service as well as voice communication due to the rapid development of technology.
- LTE Long Term Evolution
- LTE-A Long Term Evolution-Advanced
- Carrier aggregation is a technology in which a terminal transmits and receives data using a plurality of carriers. More specifically, the terminal transmits and receives data through a predetermined cell (typically a cell belonging to the same base station) of the integrated carrier, which is the same as the terminal transmits and receives data through a plurality of cells.
- Carrier aggregation is a procedure in which a base station delivers carrier information to be integrated to a terminal (this is called setting up a carrier) and activates a carrier set at a suitable time in the future. The reason for using the dual procedure of carrier setup and carrier activation is to minimize battery consumption of the terminal by driving only the transceiver for the activated carrier without always driving the transceiver for all the carriers integrated in the terminal. .
- the terminal delivers scheduling information to the base station.
- the scheduling information includes a buffer status report (BSR) and an available transmission power report (Power Headroom Report, PHR).
- BSR buffer status report
- PHR Power Headroom Report
- the theoretical maximum reverse transmission rate tends to increase in proportion to the set number of carriers, so that various inefficiencies are incurred when the buffer status is reported in the same manner as in the related art. Can be.
- the channel attributes of the set uplink carriers may vary according to the frequency band of the uplink carrier, reporting available transmission power in the same manner as in the prior art may cause various inefficiencies.
- the present invention provides a method and apparatus and a system for efficiently processing scheduling information in a mobile communication system.
- the present invention also provides a method and apparatus for efficiently processing scheduling information between a terminal and a base station in a mobile communication system supporting carrier aggregation, and a system thereof.
- the present invention also provides a method and apparatus for efficiently performing a buffer status report of a terminal in a mobile communication system supporting carrier aggregation, and a system thereof.
- the present invention also provides a method and apparatus for efficiently reporting available transmission power of a terminal in a mobile communication system supporting carrier aggregation, and a system thereof.
- a method of processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation includes receiving a control message from a base station, the control message including information on a reverse carrier added by the carrier aggregation; Determining a new buffer status table to be used for reporting the buffer status to the base station based on the information included in the control message.
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation includes receiving a control message indicating a reverse carrier configuration from a base station and determining a newly used buffer status table; Generating a MAC PDU including an identifier of the determined buffer status table and the BSR when a buffer status report (BSR) is triggered, and transmitting the MAC PDU to the base station.
- BSR buffer status report
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation receives a reverse grant indicative of initial transmission of a subframe from a base station, and receives a control channel from associated forward carriers. And receiving a buffer status report and determining a format and a buffer status value of the buffer status report when the buffer status report is triggered.
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation after receiving a reverse grant, determining whether to trigger a data channel PHR for a reverse carrier, and When the channel PHR is triggered and the reverse carrier is a primary component carrier (PCC), the control channel PHR is generated and transmitted to the base station according to whether the control channel PHR is set, and after receiving a reverse grant, Determining whether to trigger a PUSCH PHR, and if a PUSCH PHR is triggered and the reverse carrier is a primary component carrier (PCC), generating the PUCCH PHR according to whether a PUCCH PHR is set and transmitting the generated PUCCH PHR to the base station.
- PCC primary component carrier
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation includes a process of allocating an uplink resource for a new transmission from a base station, and an uplink resource for the new transmission.
- uplink resources allocated for the first time after the MAC reset driving the periodic PHR timers of the uplink carriers for which the periodic PHR timer is set.
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation may include receiving a parameter for triggering a buffer status report from a base station and activating the trigger; And checking whether the buffer status value of the buffer status report satisfies the reference buffer status value, and applying a predetermined reference trigger when the buffer status value satisfies the reference buffer status value.
- a method for processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation includes determining whether transmission output reduction occurs during reverse transmission, and when the transmission output reduction occurs. And triggering PHR of uplink carriers in which PHR is configured among uplink carriers.
- a method of processing scheduling information in a terminal of a mobile communication system supporting carrier aggregation includes receiving a control message including PHR configuration information from a base station and determining whether to trigger PHR; When triggered, the method includes transmitting the PDU including the PHR for the primary carrier and the PHR for the secondary carrier to the base station.
- FIG. 1 is a diagram showing the structure of an LTE system to which the present invention is applied;
- FIG. 2 is a diagram showing a radio protocol structure in an LTE system to which the present invention is applied;
- 3 is a diagram for explaining carrier aggregation in a terminal
- FIG. 4 is a flowchart illustrating a buffer status reporting method according to an embodiment of the present invention.
- FIG. 5 is a flowchart illustrating an operation of a terminal in a buffer status reporting method according to an embodiment of the present invention
- FIG. 6 is a flowchart illustrating an operation of a base station in a buffer status reporting method according to an embodiment of the present invention
- FIG. 7 is a diagram illustrating a structure of a MAC PDU applied to a buffer status reporting method according to an embodiment of the present invention
- FIG. 8 is a view for explaining a buffer status reporting method according to an embodiment of the present invention.
- FIG. 9 is a flowchart illustrating an operation of a terminal in a buffer status reporting method according to an embodiment of the present disclosure
- FIG. 10 is a diagram illustrating an example in which a plurality of carriers are set in a terminal in a buffer status reporting method according to an embodiment of the present invention.
- FIG. 11 is a diagram illustrating timing of a forward subframe and a reverse subframe of a terminal in a buffer status reporting method according to an embodiment of the present invention.
- FIG. 12 is a flowchart illustrating an operation of a terminal in a buffer status reporting method according to an embodiment of the present invention
- FIG. 13 is a flowchart illustrating an operation of another embodiment of a terminal in a buffer status reporting method according to an embodiment of the present disclosure
- FIG. 14 is a view for explaining a method of reporting available transmission power according to an embodiment of the present invention.
- 15 is a flowchart illustrating an operation of a terminal in an available transmission power reporting method according to an embodiment of the present invention
- 16 is a flowchart illustrating an operation of a terminal in another embodiment of a method for reporting available transmission power according to an embodiment of the present invention
- 17 is a flowchart illustrating an operation of a base station in an available transmission power reporting method according to an embodiment of the present invention
- FIG. 19 is a flowchart illustrating an operation of a terminal in an available transmission power reporting method according to an embodiment of the present invention.
- 20 is a flowchart illustrating an operation of a terminal in a buffer status reporting method according to an embodiment of the present invention
- 21 is a flowchart illustrating another operation of a terminal in a buffer status reporting method according to an embodiment of the present invention.
- 22 is a flowchart illustrating still another operation of a terminal in a buffer status reporting method according to an embodiment of the present disclosure
- FIG. 23 is a flowchart illustrating still another operation of a terminal in a method for reporting available transmission power according to an eighth embodiment of the present invention.
- FIG. 24 is a flowchart illustrating a method of changing a primary carrier according to an embodiment of the present invention.
- 25 to 27 are views for explaining a method of reporting available transmission power according to an embodiment of the present invention.
- FIG. 28 is a flowchart illustrating an operation of a terminal in another embodiment of a method for reporting available transmission power according to an embodiment of the present invention
- 29 is a block diagram showing a configuration of a terminal according to an embodiment of the present invention.
- FIG. 30 is a block diagram showing a configuration of a base station according to an embodiment of the present invention.
- the present invention relates to a method and apparatus for performing a BSR function and a PHR function by a terminal in which a plurality of carriers are integrated.
- the LTE system will be described in more detail with reference to FIGS. 1, 2, and 3.
- FIG. 1 is a diagram illustrating a structure of an LTE system to which the present invention is applied.
- a radio access network of an LTE system includes a next-generation base station (evolved Node B, ENB or Node B) 105, 110, 115, and 120 and an MME 125. And S-GW 130 (Serving-Gateway).
- the user equipment (hereinafter referred to as UE) 135 connects to an external network through the ENBs 105 to 120 and the S-GW 130.
- the ENBs 105 to 120 correspond to existing Node Bs of the UMTS system.
- the ENB is connected to the UE 135 by a radio channel and performs a more complicated role than the existing Node B.
- all user traffic including real-time services such as Voice over IP (VoIP) over the Internet protocol, is serviced through a shared channel, so information on the status of buffers, available transmit power, and channel status of UEs is available. It is necessary to have a device for scheduling the collection of this, ENB (105 ⁇ 120) is in charge.
- One ENB typically controls multiple cells.
- the LTE system uses orthogonal frequency division multiplexing (hereinafter, referred to as OFDM) in a 20 MHz bandwidth as a radio access technology.
- OFDM orthogonal frequency division multiplexing
- AMC adaptive modulation & coding
- the S-GW 130 is a device that provides a data bearer, and generates or removes a data bearer under the control of the MME 125.
- the MME is a device that is in charge of various control functions as well as mobility management function for the terminal and is connected to a plurality of base stations.
- FIG. 2 is a diagram illustrating a radio protocol structure in an LTE system to which the present invention is applied.
- the radio protocol of the LTE system includes PDCP (Packet Data Convergence Protocol 205 and 240), RLC (Radio Link Control 210 and 235) and MAC (Medium Access Control 215 and 230) in the terminal and ENB, respectively.
- the PDCP (Packet Data Convergence Protocol) 205, 240 is responsible for operations such as IP header compression / restore, and the radio link control (hereinafter referred to as RLC) 210, 235 is a PDCP PDU (Packet Data Unit). ) Is reconfigured to an appropriate size to perform ARQ operations.
- the MACs 215 and 230 are connected to several RLC layer devices configured in one terminal, and multiplex RLC PDUs to MAC PDUs and demultiplex RLC PDUs from MAC PDUs.
- MAC 215, 230 is also responsible for BSR generation and transmission, PHR generation and transmission.
- the physical layers 220 and 225 channel-code and modulate higher layer data, make an OFDM symbol, and transmit it to a wireless channel, or demodulate, channel decode, and transmit the received OFDM symbol through a wireless channel to a higher layer.
- the data input to the protocol entity based on the transmission is called a service data unit (SDU), and the output data is called a protocol data unit (PDU).
- SDU service data unit
- PDU protocol data unit
- 3 is a diagram for describing carrier aggregation in a terminal.
- a plurality of carriers are generally transmitted and received over several frequency bands.
- a carrier 315 having a center frequency of f1 and a carrier having a center frequency of f3 310 are transmitted from the ENB 305
- one terminal conventionally uses one carrier of the two carriers for data. Transmitted and received.
- a terminal having carrier aggregation capability may transmit and receive data from multiple carriers at the same time.
- the base station 305 may increase the transmission speed of the terminal 330 by allocating more carriers to the terminal 330 having carrier aggregation capability according to a situation.
- carrier aggregation may be understood as a terminal transmitting and receiving data through multiple cells at the same time. This increases the maximum transfer rate in proportion to the number of carriers integrated.
- the terminal receiving data through any forward carrier or transmitting data through any reverse carrier means that a control channel provided by a cell corresponding to a center frequency and a frequency band characterizing the carrier and It has the same meaning as transmitting and receiving data using the data channel.
- the following embodiments of the present invention will be described on the assumption of an LTE system, but the present invention can be applied to various wireless communication systems supporting carrier aggregation.
- Embodiments 1 to 3, and Embodiment 7 of the following embodiments are for a method of efficiently performing a buffer status report (BSR) of scheduling information transmitted from a mobile station to a base station.
- BSR buffer status report
- Examples> to ⁇ 6 embodiments>, ⁇ 8 embodiments>, and ⁇ 10 embodiments> relate to a method of efficiently performing available transmission power report (PHR) among the state information.
- Example 9 relates to a method of changing a primary carrier by a control message.
- the following embodiments all relate to a method of transmitting scheduling information in carrier aggregation.
- An embodiment of the present invention provides a method and apparatus for reporting a buffer status by a terminal selecting an appropriate buffer status report table.
- the terminal and the base station are each provided with a plurality of buffer status tables, the terminal and the base station how to select the appropriate buffer status table in consideration of the number of reverse carriers set in the terminal, or another predetermined condition And a device.
- the UE triggers a BSR when a predetermined condition is met, and generates and transmits a BSR when reverse transmission is possible.
- the BSR trigger condition and the like will be described later.
- the BSR is MAC control information having a predetermined format used for reporting the buffer status of the terminal.
- the BSR is information indicating how much data can be transmitted for each logical channel group of the terminal.
- the logical channel is a channel created for serving certain higher layer data.
- the logical channel may be processed in a PDCP layer and a PDCP layer configured to process service data, and a transmission buffer may be provided for each logical channel.
- a logical channel is typically set up for each user service, and priority is given to satisfy the quality of requirements of the mapped service.
- Up to 11 logical channels can be set, and the LTE system reports the buffer status for each logical channel grouping the logical channels having similar priorities instead of individually reporting the buffer status for each of the maximum 11 logical channels.
- the amount of transmittable data stored for each logical channel group is represented by 6 bit information representing a buffer status value.
- the buffer status value is a value obtained by logarithmically sampling the number of buffer status values between a predetermined minimum value and a predetermined maximum value.
- the maximum value of the buffer status value is a value set so that transmission can proceed without interruption when a predetermined buffer status report delay is assumed in a situation in which the terminal transmits at the maximum transmission rate.
- the maximum buffer status is the product of x and y.
- Factors that determine the maximum transmission rate of the terminal include the inherent performance of the terminal or the number of reverse carriers set in the terminal at any time. The number of uplink carriers set among these has a significant effect on the maximum transmission speed of the terminal. If a transmission speed of z bps is possible using one reverse carrier for a given terminal performance, z * n bps using n backward carriers is possible. Transmission speed is possible.
- a plurality of buffer status tables are defined, and the terminal and the base station report the buffer status using an appropriate buffer status table according to the maximum number of backward carriers that the terminal can use.
- a buffer state table indicating a buffer state between 0 bytes and 150000 bytes has been conventionally used.
- the conventional buffer state table will be referred to as a basic buffer state table.
- Table 1 below shows the default buffer status table in Section 6.1.3.1 of the December 2009 version of 3GPP Specification 36.321.
- the specification 36.321 in the present invention will be understood as referring to the December 2009 version of the specification 36.321.
- An example of the basic buffer state table shown in Table 1 below is shown, and the basic buffer state table is not limited to the following Table 1 in the present invention.
- the terminal and the base station include a plurality of buffer state tables including a basic buffer state table as shown in Table 1 above.
- the terminal and the base station apply a predetermined rule to determine which buffer state table from among a plurality of buffer state tables at any time.
- the predetermined rule may be, for example, the number of reverse carriers set at the corresponding time.
- a buffer state table additionally provided in addition to the basic buffer state table may be defined according to the maximum transmission speed of the terminal. For example, if the number of uplink carriers that can be configured in the terminal is n, the terminal may add n additional buffer state tables, such as a buffer state table having a maximum buffer state value twice as large as a basic buffer state table and a buffer state table as triple as three times. It can be provided.
- the terminal and the base station may have three buffer state tables, that is, a basic buffer state table, an additional buffer state table 1, and an additional buffer state table 2.
- the additional buffer state table 1 is defined on the assumption that the number of uplink carriers configured in the terminal is 2, and the maximum buffer report value is 300000 bytes.
- the additional buffer state table 2 is defined for the case where the number of uplink carriers configured in the terminal is three or more, and the maximum buffer report value is 1500000 bytes. Examples of the additional buffer state table 1 and the additional state buffer state table 2 are shown in Tables 2 and 3, respectively.
- the terminal has a basic buffer state table, an additional buffer state table 1, and an additional buffer state table 2.
- the terminal and the base station may have a larger number of buffer status tables or a smaller number of buffer status tables.
- FIG. 4 is a flowchart illustrating a buffer status reporting method according to an embodiment of the present invention.
- the terminal 405 communicates with the base station 410 in the same manner as in the conventional LTE terminal until step 420 after additionally assigning a carrier after performing the RRC connection setup process. . That is, the terminal 405 and the base station 410 transmit and receive forward data and reverse data on one forward carrier and one reverse carrier as in the case of a general LTE terminal. In this case, since the number of configured reverse carriers is one, the terminal 405 and the base station 410 use the default buffer status table (425). Thereafter, if the traffic of the terminal 405 increases at any point in step 430, the base station 410 determines to add a new carrier to the terminal 405 (Carrier Aggregation (CA) Addition).
- CA Carrier Aggregation
- the base station 410 transmits a predetermined RRC message to the terminal 405 as a control message.
- the RRC message includes information related to a newly added uplink carrier such as carrier center frequency and bandwidth information.
- the terminal 405 determines which buffer state table to use later by referring to the number of newly added uplink carriers. For example, if one reverse carrier is newly added to the terminal 405 and two reverse carriers are configured in the terminal 405, the terminal 405 uses the additional buffer state table 1. Alternatively, if two reverse carriers are newly added to the terminal 405 and a total of three reverse carriers are configured in the terminal 405, the terminal 405 uses an additional buffer state table of 2.
- the maximum reverse transmission rate is a function defined as a factor based on a reverse bandwidth, the number of transmit antennas, a modulation scheme, and the like.
- the terminal 405 and the base station 410 use a basic buffer state table if the maximum reverse transmission rate is less than x bps, an additional buffer state table 1 if it is between x bps and y bps, and an additional buffer state table 2 if y bps or more. You can also make an appointment.
- the maximum reverse transmission rates may be calculated for each uplink carrier and then summed.
- the maximum transmission rate of any reverse carrier x (UL CC x) may be calculated using, for example, Equation 1 below.
- Maximum data rate of UL CC x BW of UL CC x * maximum spectral efficiency of UL CC x.
- the terminal 405 calculates the maximum transmission rate for each reverse carrier by using the set bandwidth of the reverse carrier, whether or not MIMO is set (for example, the number of antennas to be used in the carrier), the maximum modulation order, and adds the calculated values for each reverse carrier. To calculate the sum of the maximum transmission rates of the reverse carriers.
- the terminal 405 determines which buffer state table to use after determining whether the value of the maximum reverse rate by the set or added reverse carrier corresponds to the buffer state table.
- the base station 410 may directly instruct the UE 405 which buffer state table to use.
- the information indicating the buffer status table to be used may be included in a control message (eg, an RRC message) transmitted in step 430 to add a new carrier.
- the UE 405 triggers a BSR in step 435 and transmits the triggered BSR through a predetermined procedure.
- the reason for triggering BSR is to eliminate the uncertainty that can occur when changing the buffer state table. For example, if the terminal 405 has transmitted the BSR using the previous buffer status table immediately before applying the new buffer status table, the base station 410 determines whether the BSR is based on the new buffer status table or not. You may not be able to determine correctly. In order to solve this problem, the terminal 405 triggers a regular BSR when the buffer status table is changed, and reports the buffer status to the base station 410 using the changed buffer status table as soon as possible. In step 440, when the base station 410 successfully receives the BSR, the base station 410 allocates a reverse grant to the terminal 410, and in step 445, the terminal 405 performs backward transmission using the allocated reverse grant.
- the reverse transmission in step 445 may be, for example, a response message to the RRC control message received in step 430.
- the UE 405 and the base station 410 perform reverse data transmission and reception using the new buffer state table until the buffer state table is newly changed.
- FIG. 5 is a buffer state according to an embodiment of the present invention. A flowchart illustrating the operation of the terminal in the reporting method.
- a terminal receives a control message for configuring a carrier from a base station.
- the control message for setting the carrier may be a control message for additionally setting a new carrier to the terminal, or may be a control message for removing the carrier set to the terminal.
- the terminal proceeds to step 510 and determines which buffer state table to use according to the number of the set / added uplink carriers or the maximum uplink transmission speed by the set / added uplink carrier.
- the terminal and the base station determine a buffer status table by applying a predetermined rule.
- the rule may be, for example, as follows.
- the additional buffer state table 1 is used.
- the additional buffer state table [n-1] is used.
- the maximum reverse transmission rate of the terminal is x 0 bps Less than or equal to the default buffer state table
- the additional buffer state table n is used.
- the control message transmitted in step 505 may include information indicating a buffer status table to be used by the terminal.
- the terminal uses the buffer status table indicated by the base station.
- the terminal proceeds to step 515 and checks whether the buffer status table has been changed. That is, if the UE determines to use a buffer state table different from the buffer state table previously used by receiving the control message for configuring the carrier, the terminal proceeds to step 520 to trigger the regular BSR.
- the regular BSR is a BSR triggered when data with a higher priority than data stored in the terminal occurs. Details are specified in Sections 5.4.5 and 6.1.3.1 of 36.3221. Thereafter, the terminal proceeds to step 525 to set up the reverse carrier according to the indication in the control message. After that, the buffer status value of the BSR is determined using the buffer status table determined in step 510.
- FIG. 6 is a flowchart illustrating an operation of a base station in a buffer status reporting method according to an embodiment of the present invention.
- the base station determines to additionally set a new reverse carrier to the terminal. For example, when the data demand amount of the terminal increases, the base station may additionally configure the reverse carrier.
- the base station generates and transmits a control message indicating a carrier configuration to the terminal.
- the control message may include information indicating which buffer status table the terminal should use.
- the base station determines a buffer status table that the terminal will use in the future based on the information indicated in the control message. Also, the base station can know which buffer status table the terminal uses according to rule 1 or rule 2 described above.
- the base station proceeds to step 615 and the BSR transmitted by the terminal in the future is deemed to have been generated by referring to the buffer status table indicated by the control message in step 610 and the control message is added to the control message. Accordingly, the BSR transmitted by the terminal is analyzed with reference to the changed buffer state table, and the buffer state of the terminal is determined. Accordingly, the base station can estimate the actual buffer state of the terminal from the buffer state value with reference to the changed buffer state table.
- the BSR is control information of the MAC layer in which the terminal reports the amount of data that can be transmitted to the base station.
- the control information of the MAC layer is also called a MAC control element (CE) and is stored in a MAC PDU and transmitted.
- the amount of data that can be transmitted for each logical channel group is written in the BSR, and the amount of data that can be transmitted is expressed by an index of a buffer state table.
- the index of the buffer state table will be referred to as a buffer state value in the present invention. .).
- the MAC PDU consists of a sub header part 705 and a payload part 710.
- a plurality of MAC SDUs may be stored in one MAC PDU, which is an RLC PDU which is higher layer data or a MAC CE.
- One sub-header is inserted per MAC SDU, as shown in sub-header portion 705, with each sub-header indicating a logical channel identifier 715 indicating on which logical channel the MAC SDU was generated, the size of the MAC SDU. It consists of a length field (L, Length, 720) and the like.
- the logical channel identifier 715 indicates the type of control information stored in the MAC CE.
- 11010 indicates a PHR
- 11100 to 11110 indicate various BSRs.
- three types of BSRs are defined: long BSR, short BSR, and truncated BSR.
- 11100 indicates long BSR
- 11101 indicates short BSR
- 11110 indicates truncated BSR. Details of the type of BSR are described in Section 5.4.5 and Section 6.1.3.1 of 36.321 in the LTE standard, and thus description thereof will be omitted.
- the sub header portion 705 also includes an unused R (Reserved) bit 725, an E field 730 indicating whether the last sub header is present, and an F bit 735 indicating the length of the L field.
- the unused R bit 725 is used to indicate which buffer status table the UE has generated BSR.
- the terminal and the base station are provided with four buffer status tables, and an identifier between 0 and 3 is assigned to each buffer status table, and a BSR generated by the terminal at any time is generated using the buffer status table 1. If so, for example, as shown in FIG. 8, the UE transmits by setting the R bits 810 of the sub header of the BSR 805 to “01”. Then, the base station refers to the R bits 810 in the sub header of the BSR, and determines which buffer status table the UE has generated the BSR.
- FIG. 9 is a flowchart illustrating an operation of a terminal in a buffer status report method according to an embodiment of the present invention.
- step 910 when receiving a control message indicating carrier configuration from a base station in step 905, the terminal proceeds to step 910 and determines which buffer state table to use. In this case, a predetermined identifier is allocated to each buffer status table, and the identifier information may be preset to the terminal or may be signaled to the terminal during the initial call setup process of the terminal. Thereafter, the UE waits until the BSR is triggered. If the BSR is triggered in step 915, the terminal proceeds to step 920 and generates a BSR and a subheader using the buffer status table determined in step 910. The R bits of the bus header are set in accordance with the identifier of the buffer status table referenced when the BSR is generated.
- step 925 the terminal waits until the BSR is triggered or the buffer status table is changed. Subsequently, although not shown in FIG. 9, if the BSR is triggered in step 930, the terminal proceeds to step 920, and if the buffer state table is changed, step 915.
- the MAC PDU is changed in such a manner that only the buffer status table is changed, instead of directly indicating the buffer status table used by the UE by using the R bit 725 in the sub header part 705. It is possible. That is, the terminal initializes the value of the R bit to "00" when generating a BSR for the first time. Thereafter, whenever the buffer state table is changed, the value of the R bit 725 is increased by, for example, 1, to determine whether or not the buffer state table used for the currently transmitted BSR is the same as the buffer state table used previously. Can be directed.
- the terminal 1015 receives DL CC 1 1020 and DL CC 2 1025 from the base station 1005, and DL CC 3 1030 and DL CC from the repeater 1010. A case of receiving 4 (1035) may be mentioned. Even in the case of DL CCs transmitted from the same location, if the frequency bands are different, the reception time may be minutely shifted in the terminal.
- the reception time of the DL CCs can show a significant difference.
- a reception time difference (reference number 1115) between DL CC 1 1120 and DL CC 2 1125 transmitted from the same location, or DL CC 3 1130 and DL CC 4 1135
- the reception time difference (reference number 1110) between the two is not very large, while the transmission point difference between the DL CCs (for example, DL CC 1 1120 and DL CC 3 1130) having different transmission positions (reference number 1105).
- the boundary of the reverse frame is formed when the base station moves by the interval indicated by the base frame.
- N_TA N_Timing Advance
- a DL CC providing a reference timing for a frame boundary of an arbitrary UL CC is referred to as a reference DL CC of the UL CC. Since DL CCs and UL CCs are defined in pairs in a frequency band, it is common to use DL CCs of the same frequency band as any UL CC as the reference DL CCs of the UL CCs. However, it is more preferable to define one reference DL CC for multiple UL CCs because defining reverse frame timing separately for multiple UL CCs has a side effect of increasing the complexity of the UE.
- UL CC 1 1140 is DL CC 1 1120
- UL CC 2 1145 is DL CC 2 1125
- UL CC 3 1150 is DL CC 3 1130.
- UL CC 4 1155 is the same frequency band as DL CC 4 1135, UL if frame boundary difference 1115 between DL CC 1 1120 and DL CC 2 1125 is not very large.
- a reference DL CC of CC 1 1140 and UL CC 2 1145 one of DL CC 1 1120 and DL CC 2 1125 may be used.
- DL CC 1 1120 is used as the reference DL CC
- the frame boundaries of UL CC 1 1140 and UL CC 2 1145 are all adjusted together based on DL CC 1 1120, resulting in UL CC. 1 (1140) and UL CC 2 (1145) have the same frame boundary.
- DL CC 3 1130 is set as a reference DL CC of UL CC 3 1150 and UL CC 4 1155
- the frame boundaries of UL CC 3 1150 and UL CC 4 1155 are DL CC 3 ( 1130). Accordingly, according to the above scheme, as shown in FIG.
- the same N_TA1 1160 is applied to the UL CC 1 1140 and the UL CC 2 1145, and the N_TA1 1160 is the DL CC 1 (the reference DL CC). It is applied based on the frame boundary of 1120.
- another N_TA2 1165 is applied to the UL CC 3 1150 and the UL CC 4 1155, and the N_TA2 1165 is applied based on a frame boundary of the DL CC 3 1130 which is a reference DL CC.
- the reverse grants are received by the terminal at a time difference.
- a MAC PDU generated by a reverse grant received in the nth forward subframe is transmitted in the [n + 4] th reverse subframe.
- Reverse grants for MAC PDUs transmitted on UL CCs with frame boundaries established by the same reference DL CC, if the reverse grants for the UL CCs are received by different DL CCs, are subject to some time difference. It may be received at the terminal. For example, in FIG.
- the reverse grant for the [n + 4] th subframe of the UL CC 1 1140 and the [n + 4] th subframe of the UL CC 2 1145 is the n th of the DL CC 1 1120. Since the UE is received in the subframe and the nth subframe of the DL CC 2 1125, the terminal finishes receiving the reverse grant in the DL CC 1 1120 and the timing of completing the reverse grant in the DL CC 2 1125. can be different.
- the reverse grant is transmitted in a physical downlink control channel (PDCCH) region of the forward subframe, and the UE recognizes the reverse grant in the order in which the forward subframes are received.
- PDCCH physical downlink control channel
- the terminal performs an operation in accordance with the contents of the reverse grant immediately after receiving the reverse grant. For example, when the terminal receives the reverse grant, the terminal allocates the transmission resources allocated by the reverse grant to logical channels according to the priority of the logical channel, and takes data from the logical channels according to the amount of the allocated transmission resources.
- the MAC PDU is generated by concatenating them. If the BSR is triggered at this time, the UE determines the type of BSR at the moment of receiving the first reverse grant after the BSR is triggered, that is, the type of BSR and the amount of buffer remaining after generating the MAC PDU. Initiates the operation of determining the buffer status value to be reported by the BSR.
- the operation can be proceeded quickly because the calculation operation takes an input of the amount of transmittable data and the amount of allocated transmission resources stored in the current buffer.
- another reverse grant may be received in the nth subframe of the DL CC 2 1125.
- the BSR determines the type and the buffer status value to be reported in the BSR in consideration of all backward grants.
- the UE when receiving a reverse grant indicative of 100-byte data transmission in DL CC 1 1120 of FIG. 11 and receiving a reverse grant indicative of 100-byte data transmission in DL CC 2 1125, if the UE receives Assume that you store 200 bytes of logical channel group 1 data and 200 bytes of logical channel group 2 data. If the UE determines the type of the BSR and the amount of data to be reported in the BSR by considering only the reverse grant received by the DL CC 1 1120 as in the related art, the logical channel group 1 and the logical channel group 1 may be transmitted even after transmitting 100 bytes. Since there is data in logical channel group 2, the long BSR is selected.
- Forward carriers are grouped into another group (hereinafter, reverse grant group).
- m-4 the format and content of a BSR to be transmitted in an mth subframe of a backward carrier belonging to the same backward transmission timing group
- the format and content of the BSR are determined in consideration of all backward grants to be applied in the mth subframe.
- UL CC 1 1140 and UL CC 2 1145 are one reverse transmission timing group (reverse transmission timing group 1), and UL CC 3 1150 and UL CC 4 1155 are different. It may be set to a reverse transmission timing group (reverse transmission timing group 2).
- DL CC 4 1135 are related to each other in terms of uplink scheduling, the uplink grant group corresponding to uplink transmission timing group 1 is DL CC 1 1120 and DL CC 2 1125 according to the third embodiment.
- the reverse grant groups corresponding to the uplink transmission timing group 2 are DL CC 3 1130 and DL CC 4 1135.
- FIG. 12 is a flowchart illustrating an operation of a terminal in a buffer status report method according to an embodiment of the present invention.
- step 1210 the UE waits until the PDCCH reception is completed from all forward carriers belonging to the same reverse grant group as the forward grant.
- the base station instructs the terminal which reverse carriers have the same backward transmission timing as the first information.
- the base station also indicates to the terminal which forward carrier can be received from which forward carrier for each reverse carrier.
- the terminal recognizes forward carriers belonging to the same reverse grant group by using the two pieces of information.
- the terminal recognizes forward carriers to which a reverse grant can be transmitted and received for reverse carriers having the same backward transmission timing as forward carriers belonging to the same reverse grant group.
- UL CC 1 1140 and UL CC 2 1145 share the same backward transmission timing (ie, have the same reverse frame boundary), and the reverse grant for UL CC 1 1140 is DL CC 1 ( Through 1120, if a reverse grant for UL CC 2 1145 can be received via DL CC 2 1125, DL CC 1 1120 and DL CC 2 1125 belong to the same reverse grant group.
- Waiting until PDCCH reception is completed from forward carriers belonging to the same reverse grant group means receiving a signal transmitted in the PDCCH region of the forward carriers and completing the interpretation of the signal. In other words, determining whether or not a reverse grant has been received on the forward carriers.
- the UE When the UE completes the reception of the PDCCH of the DL CCs for the n th reverse subframe, the UE proceeds to step 1215 and checks whether a regular BSR or a periodic BSR is triggered. If one of the two BSRs is triggered, the terminal proceeds to step 1230.
- the reverse grants transmitted and received by the DL CC 1 1120 for the same reverse subframe from the first grant to the one before the last grant are DL CCs. 2
- the reverse grant received at DL CC 1 1120 is the first grant
- the reverse grant received at DL CC 2 1125 is the last grant.
- the data to be stored in the MAC PDU to be generated is determined.
- Determining data to be stored for each reverse grant is also referred to as performing a logical channel priority process, which is described in detail in Section 5.4.3.1 of 36.321 in the LTE specification.
- the UE performs a logical channel priority process for each reverse grant from the first grant to the last second grant to determine which logical channel group in the MAC PDU is to receive how many bytes of data in step 1235.
- the UE subtracts the amount of data to be stored in the MAC PDUs generated by the grants other than the last grant in step 1235 from the amount of transmittable data stored by the UE at that time, the logical data that can be transmitted remains.
- the number of channel groups is used to determine whether to generate a long BSR or a short BSR.
- the terminal For example, two reverse grants each indicating 100 bytes of data transmission are received, and the terminal stores 100 bytes of data in logical channel group 1 and 500 bytes of data in logical channel group 2.
- the UE decides to store 100 bytes of data in the MAC PDU in the logical channel group 1, and thus the remaining transmittable data is 500 bytes of the logical channel group 2.
- the terminal After determining the format of the BSR as described above, the terminal proceeds to step 1240 to determine the logical channel group and the amount of data to be stored in the last MAC PDU and proceeds to step 1245.
- the UE determines the amount of data (buffer state value) to be reported in the BSR in consideration of the amount of data to be stored in the last MAC PDU. That is, a buffer state value corresponding to a value obtained by subtracting the amount of data to be stored in all MAC PDUs including the last MAC PDU from the transmittable data stored in the current UE for each logical channel group is selected.
- the UE determines whether the padding space exists in each MAC PDU and determines not to insert the padding BSR even if there is enough padding space to accommodate the padding BSR. This is for transmitting only one BSR in MAC PDUs transmitted in the same subframe.
- the MAC PDUs may arrive at the base station at different times, which is a result of the base station misidentifying the buffer status of the UE. Since only one MAC PDU can receive a BSR when multiple MAC PDUs are transmitted in the same reverse subframe. Proceeding to step 1250 means that a periodic BSR or regular BSR is already transmitted, so that even if the padding space is sufficient, the padding BSR is not used. Therefore, although the padding BSR is stored in one MAC PDU among the plurality of MAC PDUs in step 1225, the padding BSR is not stored in any MAC PDU among the plurality of MAC PDUs in step 1250.
- step 1220 determines data to be stored in MAC PDUs corresponding to the received reverse grants.
- step 1225 it is checked whether there is a MAC PDU that can accommodate the padding BSR. If there are a plurality of MAC PDUs that can accommodate the padding BSR, the UE stores the padding BSR in the MAC PDU having the largest padding space or the padding BSR in one selected MAC PDU, and stores the padding BSR in the remaining MAC PDUs. Decide not to. This is to prevent the short padding BSR from being stored even though the padding space is not sufficient and the number of logical channel groups in which data that can be transmitted is stored is two or more. After determining whether to receive the padding BSR in step 1250 or 1225, the UE generates MAC PDUs in step 1255 and transmits the MAC PDUs to the physical layer to be transmitted in the nth subframe.
- the UE In determining which logical channel group data is to be stored in the MAC PDUs to be transmitted in the same reverse subframe, the UE adds all the received reverse grants for the reverse subframe according to another embodiment of the third embodiment.
- the logical channel priority process may be performed only once using the reverse grant.
- the present invention is applicable.
- the UE determines the format of the BSR before performing the logical channel prioritization process, and determines the contents of the BSR after performing the logical channel prioritization process, the UE operation shown in FIG. 12 is applied as it is.
- step 1335 of FIG. 13 the UE determines the format of the BSR in consideration of the number of logical channel groups storing data that can be transmitted at a corresponding time.
- step 1340 of FIG. 13 all of the uplink grants are added to perform a logical channel priority process, and the logical channel group and amount of data to be stored for each MAC PDU are determined.
- steps 1345, 1350, and 1355 are the same as steps 1245, 1250, and 1255 in FIG. 12, and thus a detailed description thereof will be omitted.
- step 1320 of FIG. 13 is the same as step 1340
- step 1325 is the same as step 1225.
- the base station determines which uplink carriers have the same uplink frame timing and notifies the terminal.
- the UE considers the size of all MAC PDUs to be transmitted in the backward carrier having the same backward frame timing as the subframe and the type of data to be stored. . That is, after determining how much data is included in which logical channel group in all MAC PDUs to be transmitted in the reverse carrier having the same backward frame timing, the amount of data for each logical channel group to be reported in the BSR is determined.
- the padding BSR may be included only in the selected MAC PDU, and the padding may be included in the free space of the remaining MAC PDUs. In this case, the padding BSR is not stored in the remaining MAC PUDs.
- the terminal has a power headroom report (PHR) function to assist scheduling of the base station.
- PHR power headroom report
- the terminal stores the MAC control element (CE) called PHR in the MAC PDU and transmits it to the base station.
- CE MAC control element
- the PHR stores a difference value between the required transmit power required for the MAC PDU transmission and the maximum transmit power of the terminal.
- the required transmission power is calculated by considering the amount of transmission resources used for the MAC PDU transmission, MCS level, path loss of the associated forward carrier, and the like. Details are described in 5.1.1 of 36.213 in the LTE specification. have. Since the PHR is associated with a MAC PDU transmitted through a physical uplink shared channel (PUSCH), it is referred to as a PUSCH PHR.
- PUSCH physical uplink shared channel
- the PHR function may be set for each reverse carrier.
- the PHR function may be extended to a physical uplink control channel (PUCCH). If the base station recognizes the information on the transmission power used by the terminal in the PUCCH transmission, the base station can more accurately determine how to allocate the PUSCH transmission resources in the subframe in which the PUCCH is transmitted.
- PUCCH PHR the PHR associated with PUCCH transmission will be referred to as PUCCH PHR.
- the PUCCH PHR function is linked with the PUSCH PHR function of a specific reverse carrier, thereby eliminating the need for a separate logical channel identifier indicating the PUCCH PHR and avoiding the inconvenience of separately defining the PUCCH PHR trigger conditions. To present.
- the PUCCH is a signal transmitted through a transmission resource having a predetermined period previously allocated to the terminal, the channel quality information (CQI), the reverse HARQ feedback information, and the dedicated scheduling request (D-SR), which report the forward channel state of the terminal. Terminal is used for requesting transmission resource allocation to the base station).
- the PUCCH signals are transmitted only through a specific carrier called a primary component carrier (PCC) among a plurality of uplink carriers configured in the terminal. Therefore, unlike the PUSCH PHR that can be set individually for multiple reverse carriers, the PUCCH PHR is set only for the reverse PCC. Furthermore, if the PUSCH PHR is already configured in the reverse PCC, the trigger condition of the PUCCH PHR may be associated with the trigger condition of the PUSCH PHR.
- the PUCCH PHR is triggered when the PUSCH PHR is triggered in the reverse PCC. Since the PUSCH PHR trigger condition is defined in consideration of the properties of the uplink carrier, even if a channel having different properties of PUSCH and PUCCH is transmitted on the same carrier, it is not a problem even if the same trigger condition is applied. Finally, if the PUCCH PHR is defined to be always transmitted together with the PUSCH PHR, there is no need to use a separate logical channel identifier for the PUCCH PHR. For example, referring to FIG.
- the PHR MAC CE when a PHR MAC CE is stored in an arbitrary MAC PDU, that is, when the logical channel identifier 1405 of the subheader indicates the PHR MAC CE, the PHR MAC CE is assigned to the reverse PCC. If the PHR MAC CE, as shown in FIG. 14A, both the PUSCH PHR 1410 and the PUCCH PHR 1415 are stored in the PHR MAC CE, and if the PHR MAC CE is not for the reverse PCC, FIG. As described above, only the PUSCH PHR 1425 is accommodated in the PHR MAC CE. There are two ways to indicate which UL CC a PHR MAC CE relates to.
- the PHR for any UL CC may be limited to be transmitted only through the corresponding UL CC. Therefore, if the first method is used, when a predetermined field of the PHR MAC CE or a predetermined field of the subheader for the PHR MAC CE indicates a reverse PCC, both the PUSCH PHR and the PUCCH PHR are stored in the corresponding PHR MAC CE, If the field indicates a UL CC other than the reverse PCC, only the PUSCH PHR is stored in the corresponding PHR MAC CE.
- both PUSCH PHR and PUCCH PHR are stored in PHR MAC CE of MAC PDU transmitted through UL PCC, and only PUSCH PHR is stored in PHR MAC CE of MAC PDU transmitted through UL CC other than UL PCC. do.
- FIG. 15 is a flowchart illustrating an operation of a terminal in a method for reporting available transmission power according to an embodiment of the present invention, which illustrates a terminal operation when a PUSCH PHR for a certain UL CC is transmitted only in a corresponding UL CC.
- step 1505 backward transmission resources for new transmission are available for the UL CC, such as backward transmission resources indicating new transmission in an arbitrary UL CC.
- step 1510 the UE checks whether a PUSCH PHR for the UL CC is triggered.
- the PUSCH PHR is triggered, for example, when the periodic PHR timer expires or when the path loss change of the associated forward carrier is above a predetermined reference value. If the PUSCH PHR is triggered, the UE proceeds to step 1515 to check whether the UL CC triggered by the PUSCH PHR is PCC. If the PCC, the terminal proceeds to step 1520.
- step 1530 the UE checks whether the PUCCH PHR is configured.
- the PUCCH PHR may or may not be set according to the decision of the network (eg, base station). If the PUCCH PHR is not configured, even if the PUSCH PHR for the UL PCC is triggered, the PUCCH PHR should not be triggered. If the PUCCH PHR is configured, the terminal proceeds to step 1525. In step 1525, the UE generates a PHR MAC CE including both available transmission power information for the PUSCH and available transmission power information for the PUCCH.
- PUSCH available transmit power information and PUCCH available transmit power information for example, each has a size of 1 byte, and available transmit power information may be written in the remaining 6 bits except the preceding two bits.
- the UE proceeds to step 1535 to generate a MAC PDU. That is, MAC SDUs and MAC subheaders to be included in the payload portion of the MAC PDU are concatenated in order. Since the PHR MAC CE contains both of the available transmit power information for the PUSCH and the available transmit power information for the PUCCH, the PHR MAC CE has a size of, for example, 2 bytes.
- the terminal writes a logical channel identifier indicating the PHR in the MAC subheader of the PHR MAC CE.
- the UE proceeds to step 1530, the UE generates a PHR MAC CE containing only available transmission power information for the PUSCH.
- the PHR MAC CE which only contains available transmission power information for the PUSCH, has a size of, for example, 1 byte as in the prior art.
- the terminal proceeds to step 1535 to generate the MAC PDU.
- the PHR MAC CE has a size of 1 byte, for example, and a logical channel identifier indicating a PHR is written in the MAC subheader of the PHR MAC CE.
- FIG. 16 is a flowchart illustrating an operation of a terminal in another embodiment of an available transmission power reporting method according to an embodiment of the present invention.
- This is a UL in which a PHR is assigned to a predetermined field of a PHR MAC CE or a predetermined field of a corresponding subheader. It shows the terminal operation when the information indicating whether or not to the CC is stored.
- a backward transmission resource for new transmission is available for a corresponding UL CC, for example, because a backward transmission resource indicating new transmission is allocated in a certain UL CC.
- the UE checks whether there is a UL CC triggered by the PUSCH PHR among UL CCs for which the PHR function is set.
- the PUSCH PHR is triggered, for example, when the periodic PHR timer expires or when the path loss change of the associated forward carrier is above a predetermined reference value. If the PUSCH PHR is triggered in any UL CC, the UE proceeds to step 1615 to check whether the UL CC triggered by the PUSCH PHR is PCC.
- step 1620 the terminal checks whether the PUCCH PHR is set. PUCCH PHR may or may not be set according to the decision of the network. If the PUCCH PHR is not configured, even if the PUSCH PHR for the UL PCC is triggered, the PUCCH PHR should not be triggered. If the PUCCH PHR is configured, the terminal proceeds to step 1625. In step 1625, the UE generates a PHR MAC CE including both available transmission power information for the PUSCH and available transmission power information for the PUCCH.
- the UE After generating the PHR MAC CE, the UE proceeds to step 1535 to generate a MAC PDU. That is, MAC SDUs and MAC subheaders to be included in the payload portion of the MAC PDU are concatenated in order. . Since the PHR MAC CE contains both of the available transmit power information for the PUSCH and the available transmit power information for the PUCCH, the PHR MAC CE has a size of, for example, 2 bytes. The logical channel identifier indicating the PHR is written in the MAC subheader of the PHR MAC CE. In addition, the first two bits of the MAC subheader contain an identifier indicating which UL CC the PHR MAC CE is.
- the UE When the UE proceeds to step 1630, it generates a PHR MAC CE containing only available transmission power information for the PUSCH.
- the PHR MAC CE which only contains available transmission power information for the PUSCH, has a size of, for example, 1 byte as in the prior art.
- the terminal After generating the PHR MAC CE, the terminal proceeds to step 1535 to generate the MAC PDU.
- the PHR MAC CE has a size of 1 byte, and a logical channel identifier indicating a PHR is written in the MAC subheader of the PHR MAC CE.
- the first two bits of the MAC subheader contain an identifier indicating which UL CC the PHR MAC CE is.
- FIG. 17 is a flowchart illustrating an operation of a base station in a method for reporting available transmission power according to an embodiment of the present disclosure.
- the base station proceeds to step 1710.
- the base station determines whether the UL CC received by the PHR MAC CE is a UL PCC, and the PHR MAC CE is UL. Determine if it is for PCC or not.
- the base station proceeds to step 1720 and checks whether the PUCCH PHR is configured in the terminal. If the PUCCH PHR is configured, the base station proceeds to step 1725 and demultiplexes the available transmit power information for the PUSCH and the available transmit power information for the PUCCH from the received MAC PDU and proceeds to step 1735.
- step 1715 the base station proceeds to step 1730 to demultiplex available transmit power information for the PUSCH from the MAC PDU and to step 1735. Proceed to Subsequently, in step 1735, the base station interprets the MAC subheader, demultiplexes the remaining MAC SDUs, and delivers them to the appropriate device.
- FIG. 28 is a flowchart illustrating an operation of a terminal in another embodiment of the method for reporting available transmission power according to the fourth embodiment of the present invention.
- step 2810 the terminal proceeds to step 2810 to check whether the PUSCH PHR of the PCell should be transmitted.
- PCell has a similar meaning to the primary carrier as presented in TS 36.300. If the PUSCH PHR of the PCell is to be transmitted, for example, the change in path loss exceeds a reference value or the periodic timer expires is the case where the PUSCH PHR of the PCell is to be transmitted. If the PUSCH PHR transmission of the PCell is necessary, the terminal proceeds to step 2815, otherwise proceeds to step 2835. In step 2815, the UE checks whether simultaneous transmission of the PUCCH and the PUSCH is possible.
- PUCCH and PUSCH can be simultaneously transmitted is related to UE-specific capability and may or may not be simultaneously transmitted depending on the UE.
- the terminal capable of simultaneous transmission reports the PUCCH PHR and the PUSCH PHR together and proceeds to step 2825.
- the UE calculates the available transmit power of the PUCCH and the available transmit power of the PUSCH.
- the UE generates a PHR MAC CE (Control Element) containing the available transmit power information of the PUCCH and the available transmit power information of the PUSCH. do.
- the terminal stores a predetermined Logical Channel Identification (LCID) in a MAC subheader of the PHR MAC CE to indicate that the MAC CE is a PHR MAC CE.
- LCID Logical Channel Identification
- step 2815 If it is determined in step 2815 that simultaneous transmission of the PUCCH and the PUSCH is not possible, the UE proceeds to step 2820 to calculate available transmission power of the PUSCH and proceeds to step 2830 to include the PHR MAC containing the available transmission power information of the PUSCH.
- Generate CE A predetermined LCID is stored in a MAC subheader of the PHR MAC CE to indicate that the MAC CE is a PHR MAC CE.
- only a predetermined terminal reports a PUCCH PHR and a PUSCH PHR according to a capability of the terminal, a terminal configuration, and the like, and the predetermined terminal reports only the PUSCH PHR.
- the UE reporting PUCCH PHR and PUSCH PHR together always triggers and transmits PUSCH PHR and PUCCH PHR together
- PHR containing PUSCH PH and PUCCH PH together and PHR containing only PUSCH PH together use the same LCID. . In other words, there is no need to use a separate LCID for the PUCCH PH.
- the UE generates and transmits the MAC PDU.
- the MAC PUD may accommodate the PHR MAC CE.
- the PHR function is not always required for the reverse carrier. For example, if all of the associated forward carriers in terms of scheduling and any reverse carrier are inactive, or if the channel state of the forward carrier that provides the path loss for calculating the reverse transmit power of the reverse carrier is considered to be out of service, then Data transmission on the reverse carrier is impossible. Even in this situation, operating the PHR function of the reverse carrier results in unnecessary operations such as timer operation and decision on whether to determine whether to trigger the PHR.
- a method of temporarily stopping a PHR function of a corresponding reverse carrier is provided in the above situation.
- FIG. 18 is a flowchart illustrating an operation of a terminal in a method for reporting available transmission power according to an embodiment of the present disclosure.
- a PHR function is set in an arbitrary reverse carrier of a terminal.
- the establishment of the PHR function on any reverse carrier means that a periodic PHR timer, path loss change criterion is set for the carrier.
- the UE determines whether to trigger the PHR for the corresponding uplink carrier using the informed timer value of the periodic PHR timer and the path loss change criteria.
- the UE monitors a forward carrier associated with a reverse carrier for which the PHR function is set.
- the forward carriers to be monitored include forward carriers associated with the corresponding backward carriers in terms of scheduling and forward carriers associated with path loss.
- the association of any reverse carrier with any forward carrier in terms of scheduling means that a scheduling instruction (reverse grant) for the reverse carrier is transmitted and received only on the forward carrier.
- the association may be set in a control message indicating a carrier setup.
- the association of any reverse carrier with any forward carrier in terms of path loss means using the path loss of the associated forward carrier in calculating the transmit power of the reverse carrier.
- the association may be set in a control message for establishing a carrier.
- the association in terms of the scheduling and the association in terms of path loss may or may not be the same.
- the UE proceeds to step 1815 and checks whether a related forward carrier is in an inactive state in terms of scheduling.
- any forward carrier is inactive, it means that the UE does not receive the PDCCH of the forward carrier.
- the base station leaves the other carriers except the necessary carriers among the forward carriers configured in the terminal in an inactive state. Activating or deactivating any forward carrier may be accomplished by the base station sending an explicit control command to the terminal. If all of the forward carriers associated with the uplink carrier with the PHR function set up are inactive, this means that scheduling for the uplink carrier is impossible. Therefore, the necessity of performing the PHR function is reduced, and the terminal proceeds to step 1830. If at least one associated forward carrier is active in terms of scheduling and uplink carrier configured with the PHR function, the terminal proceeds to step 1820.
- step 1820 the UE checks whether the forward carrier associated with the backward carrier and the path loss is in a state in which normal reception is impossible due to poor channel reception quality. The determination is determined whether the channel reception quality of the forward carrier is longer than a predetermined reference value for a predetermined period. If normal service is not available on the associated forward carrier in terms of path loss in step 1820, it is highly likely that normal backward transmission will be difficult due to high path loss in reverse transmission on the reverse carrier. Therefore, the terminal proceeds to step 1830 to deactivate the PHR function. Deactivating the PHR function may mean stopping the driving of the periodic PHR timer and discarding the stored information to determine whether the PHR is triggered.
- the terminal proceeds to step 1825 to activate the PHR function. If the PHR function has already been activated, the current PHR function remains active. Enabling the PHR function means driving a periodic PHR timer and checking the path loss change during reverse transmission to determine whether to trigger the PHR. If the PHR function is changed from an inactive state to an activated state in step 1825, the terminal drives a periodic PHR timer and newly triggers the PHR. The change in the PHR function from the deactivated state to the activated state for any reverse carrier is for reporting the PHR to the base station because there is a high possibility that the PHR has not been reported for the reverse carrier for a long time.
- the PHR function is set for each reverse carrier, it means that the PHR timer is driven independently for each carrier and the PHR is triggered independently.
- the PHR timer is for periodic transmission of the PHR.
- the PHR timer is started.
- the expiration of the periodic PHR timer triggers the PHR.
- the triggered PHR is generated at the closest point in time for which backward transmission is possible (eg, when receiving a reverse grant for the first time after the PHR is triggered) and is received and transmitted in a MAC PDU.
- the operation of the PHR timer and the transmission of the PHR have a cyclical relationship.
- the PHR timer is stopped due to handover or the like, the PHR timer is not restarted unless a new PHR is transmitted after the handover is completed.
- the terminal stops all timers running in the MAC layer. If the stopped PHR timer is not restarted after the handover is completed, the result is that the periodic PHR function is inadvertently stopped.
- the PHR timer in order to solve the problem that the PHR timer is not restarted after the handover as described above, it is defined to drive the PHR timer when the terminal performs the first backward transmission in a new cell after the handover.
- the PHR timer of the corresponding carrier is driven after performing the first uplink transmission on any carrier in the new cell as described above, a significant delay may occur until all the PHR timers of the uplink carriers for which the PHR timer is set are restarted.
- the PHR is less important than the BSR, so there is no need to trigger the PHR as soon as the handover is complete. Even so, it is necessary to transmit the PHR as soon as possible to a base station having no information on the available transmission power of the terminal.
- a method of driving the periodic PHR timers of all the backward carriers in which the periodic PHR function is set together is provided.
- step 19 is a flowchart illustrating an operation of a terminal in a method for reporting available transmission power according to an embodiment of the present disclosure.
- a reverse transmission resource indicating a new transmission in an arbitrary UL CC is allocated. For example, backward transmission resources for new transmission are available for the corresponding UL CC.
- the terminal proceeds to step 1910 and checks whether the newly available transmission resource for the new transmission is the transmission resource for the new transmission first available after the MAC reset. If so, the process proceeds to step 1915 to drive all the periodic PHR timers of the reverse CCs in which the periodic PHR timer is set.
- the UE Since the timers are stopped while the terminal performs the MAC reset, if the timer is not restarted after the MAC reset, the periodic PHR function may be inadvertently deactivated.
- the UE In step 1920, the UE generates a MAC PDU to be transmitted through the available transmission resource and transmits a MAC PDU through the transmission resource. If it is not the first resource allocation after the MAC reset in step 1910, the UE performs a general UL transmission.
- a new buffer status reporting trigger is proposed as a method for efficiently reporting a buffer status of a terminal to a base station in a high speed data communication environment.
- a buffer state reported by a terminal is rapidly changed when the base station does not recognize the state of a buffer. Can change. For example, even though the terminal stores 1,000,000 bytes of transmittable data, due to the limitation of the buffer status table, the terminal may report that the amount of data that can be transmitted is 150,000 bytes or more (for example, the terminal may report the buffer status value of the basic buffer status table). Report 63).
- the base station does not know how much data the terminal is storing. Therefore, the grant cannot be properly allocated to the terminal until a new buffer status report is received later. As such, after the UE transmits a large amount of data, the necessity of triggering a new buffer status report increases.
- a transmission amount reference trigger method for triggering a buffer status report whenever a UE transmits a predetermined amount or more of data is provided.
- the transmission amount reference trigger method is already widely used and takes a predetermined operation after the terminal transmits data over a predetermined reference value. If the conventional method is applied as it is, there is a disadvantage in that the buffer status report is unnecessarily frequently generated.
- the problem to be solved by the present invention is that when the buffer state of the terminal changes significantly from the most recently reported buffer state, in particular, when the base station cannot estimate the change in the buffer state of the terminal (for example, the buffer state).
- the buffer status report is provided when the terminal provides incomplete information to the base station due to the limit of the maximum value of the table. Therefore, triggering a buffer status report every time a certain amount of data is sent can cause the problem of generating too many buffer status reports.
- Another method proposed in the present embodiment proposes a method of triggering a buffer status report when a certain amount of data is transmitted from the most recent buffer status report to compensate for this problem.
- the counter that records the amount of transmitted data is not initialized to 0 only when the count value exceeds a predetermined reference value as in the prior art, but for other reasons (high priority data generation, padding BSR generation, etc.).
- the buffer status report is triggered, it initializes to 0 to prevent BSR from occurring unnecessarily frequently.
- the transmission amount reference trigger is most useful when the terminal reports the amount of data out of the range indicated by the buffer status table, the transmission amount reference trigger is determined according to the buffer status value reported in the most recently transmitted buffer status report. You can optionally apply a trigger.
- the transmission amount reference trigger may be applied only when the highest value is reported as the buffer state value or when a predetermined reference value or more is reported as the buffer state value.
- FIG. 20 is a flowchart illustrating an operation of a terminal in a buffer status reporting method according to an embodiment of the present invention.
- a new trigger for buffer status reporting is defined.
- the parameter may include a transmission amount reference and a reference buffer status value (s).
- the reference buffer state value is a reference value for determining whether the transmission amount reference trigger is applied.
- the terminal activates the transmission amount reference trigger when a buffer status report containing a buffer status value corresponding to the reference buffer status value is triggered.
- a value previously promised between the terminal and the base station may be used, or the highest value of the buffer state table may be used as the reference buffer state value.
- step 2010 the UE waits for the first buffer status report to be triggered. If the buffer status report is triggered, the terminal proceeds to step 2015 and checks whether the buffer status value included in the triggered buffer status report corresponds to the reference buffer status value. do.
- the reference buffer status value may be a maximum value defined in the buffer status table (for example, the buffer status value 63) or the value (s) reported in step 2005. If the buffer status value of the buffer status report matches one of the reference buffer status values, the terminal proceeds to step 2020 to apply the transmission amount reference trigger. If the buffer state value of the buffer status report does not match any of the reference buffer states, the terminal proceeds to step 2035 to deactivate the transmission amount reference trigger.
- Deactivating the transmission amount reference trigger means that the terminal does not perform any operation related to the transmission amount reference trigger, for example, the operation of managing the aforementioned COUNT.
- the terminal initializes COUNT to zero. When data is transmitted in the reverse direction, each time data is transmitted, the amount of data transmitted is accumulated in COUNT.
- the UE checks whether a predetermined BSR is triggered before the counter exceeds a reference value in step 2025.
- the predetermined BSR may be, for example, all other BSR except for Truncated BSR (see 3GPPP TS 36.321) that delivers incomplete information to the base station due to lack of padding space, that is, a regular BSR, a periodic BSR, and a padded BSR.
- the triggering of the BSR corresponding to the predetermined BSR before the COUNT exceeds the reference value means that the UE newly reports the buffer status of the UE to the base station, and thus it is not necessary to trigger the transmission amount reference BSR.
- the terminal proceeds to step 2015 and resumes the determination of whether to activate the transmission amount reference trigger. For example, a subsequent operation such as determining whether to apply a transmission amount reference trigger by checking a buffer state value of the newly triggered BSR is performed. If the predetermined BSR is not triggered until the COUNT exceeds the reference value in step 2025, the UE triggers a periodic BSR at the time when the COUNT exceeds the reference value and initializes the COUNT to 0. Return to Triggering the periodic BSR means that the UE does not transmit a scheduling request signal to transmit the BSR. For reference, when the regular BSR is triggered, the terminal transmits a scheduling request signal to quickly transmit the BSR.
- COUNT increments by the amount of data transferred each time data is transferred. At this time, it is possible to increase the COUNT only for data belonging to a specific logical channel group.
- the specific logical channel group may be, for example, a logical channel group whose buffer status value is greater than or equal to the reference buffer status value in the most recently reported BSR.
- FIG. 21 a method of triggering a BSR when a predetermined ratio or more data is transmitted in a buffer state most recently reported by the UE is illustrated in FIG. 21.
- 21 is a flowchart illustrating another operation of a terminal in a buffer status reporting method according to an embodiment of the present invention.
- a UE is notified of parameters related to a transmission rate reference trigger from a base station through a call setup process.
- the parameter consists of a parameter defining the triggering condition of the transmission rate reference trigger, that is, the transmission rate reference, and a parameter defining the application condition of the transmission rate reference trigger, i.
- the reference buffer size may be used instead as a parameter that defines the application condition of the transmission rate reference trigger.
- the reference buffer state value is a kind of index as described above. In some cases, it may be more preferable to determine whether the transmission rate reference trigger is applied based on the total amount of data reported in the buffer status report. In this case, the data stored in the actual buffer called the reference buffer size is indicated in bytes. Use a reference buffer size. Similarly, the condition of applying the transmission amount reference trigger may use a reference buffer size indicating data stored in the buffer in bytes.
- step 2110 the UE waits for the first buffer status report to be triggered. If the buffer status report is triggered, the UE proceeds to step 2115 to determine whether to apply the transmission rate reference trigger. In step 2115, the UE determines whether the buffer status value of the triggered buffer status report matches one of the reference buffer status values, or the entire buffer status that can be derived from the buffer status value of the triggered buffer status report is a reference buffer status. It is determined whether or not it is abnormal.
- the total buffer state is a value obtained by applying a predetermined rule from the buffer state values of the buffer state report.
- the total buffer status can be defined as the sum of the maximum (or minimum) values of the range indicated by each buffer status value, which is 242 bytes (or 209 bytes) in this example. If the reference buffer state is 1000 bytes, the transfer rate reference trigger does not apply. If the reference buffer state is 200 bytes then the transfer rate reference trigger is applied. The determination of whether to apply the transmission rate reference trigger in step 2115 is applicable to the determination of whether to apply the transmission amount reference trigger in step 2115.
- the terminal proceeds to step 2120. If the transmission rate reference trigger is not required, the terminal proceeds to step 2135 to deactivate the transmission rate reference trigger. .
- the deactivation of the transmission rate reference trigger means that the terminal does not perform any operation related to the transmission rate reference trigger, for example, an operation of managing a transmission rate variable.
- the terminal initializes the transmission rate variable to zero. Whenever data is transmitted in the reverse direction, the ratio of the cumulative value of the transmitted data and the comparison value is stored in the transmission rate variable. The comparison value is the sum of the data reported in the most recently triggered (or transmitted) buffer status report.
- the UE checks whether the BSR is triggered before the transmission rate variable exceeds a reference value in step 2125.
- the BSR may be any other BSR except for a Truncated BSR (see 36.321) that delivers incomplete information to a base station due to lack of padding space, for example.
- step 2115 If the BSR is triggered before the transmission rate exceeds the reference value, the terminal proceeds to step 2115 and checks again whether or not the transmission rate reference trigger is activated. If the BSR is not triggered until the transmission rate exceeds the reference value, the terminal proceeds to step 2130 and triggers a periodic BSR when the transmission rate exceeds the reference value and returns to step 2115.
- a method is provided so that a BSR is always triggered when backward data of a predetermined size or more is transmitted.
- a significant change in the buffer state that is, a sudden decrease in the buffer state, increases the need to trigger a new BSR.
- the size of the BSR is fixed, and the overhead caused by the BSR is relatively small.
- 22 is a flowchart illustrating still another operation of a terminal in a buffer status reporting method according to an embodiment of the present invention.
- the UE recognizes a trigger related parameter.
- the trigger related parameter is information indicating how many bytes or more of the MAC PDU should be included in the transmission of the BSR.
- the UE proceeds to step 2215 and checks how many bytes of MAC PDU size indicates the reverse grant indicating the new transmission. If the size of the MAC PDU exceeds the reference size compared to the reference size recognized in step 2205, the procedure proceeds to step 2220 to trigger a periodic BSR. If the size of the MAC PDU is smaller than the reference size, the terminal proceeds to step 2225 to operate according to the prior art.
- the terminal if the request transmission output exceeds the maximum transmission output of the terminal, the terminal lowers the transmission output to the maximum transmission output and transmits it. This is referred to as power scaling.
- the reduction of the transmission output is a strong proof that the base station is mistaken for the transmission output situation of the terminal. Therefore, the terminal needs to notify the base station of the transmission output status by transmitting the PHR.
- the terminal needs to notify the base station of the transmission output status by transmitting the PHR.
- PHR transmission is likely to fail.
- the UE if the UE is expected to reduce transmission power in any subframe, the UE triggers PHR of all uplink carriers scheduled for data transmission in the subframe and improves reliability of the transmission. In order to provide a method for triggering PHR again after transmitting the PHRs.
- the reduction of the transmission power has the same meaning as the shortage of the transmission power.
- FIG. 23 is a flowchart illustrating an operation of a terminal in a method for reporting available transmission power according to an eighth embodiment of the present invention.
- the reverse transmission resource may be for one reverse carrier or may be for multiple reverse carriers.
- the UE determines whether transmission output reduction occurs during the reverse transmission. If the reverse transmission is performed over a plurality of reverse carriers, for example, if the reverse transmission resource available in step 2305 is to transmit X bytes of data in reverse carrier 1 and 2 to Y bytes of data in reverse carrier, Although the required transmission power of the individual reverse transmission of the reverse carrier does not exceed the maximum transmission output of the terminal, the sum of the required transmission power for each reverse carrier exceeds the maximum transmission output of the terminal, thereby reducing transmission output.
- step 2315 the UE triggers PHR of uplink carriers for which PHR is configured among uplink carriers related to uplink transmission in which the transmission output reduction occurs. For example, if the reverse carrier 1, the reverse carrier 2, the reverse carrier 3 is configured in the terminal, PHR is set in all the reverse carriers, and the transmission by performing the reverse transmission at the same time in the reverse carrier 1 and the reverse carrier 2 in any subframe
- the UE triggers PHR of the uplink carrier 1 and the uplink carrier 2. The process then proceeds to step 2330.
- the terminal proceeds to step 2320, and determines whether the periodic PHR or regular PHR occurs.
- the terminal proceeds to step 2325 and ends the process without generating a PHR. If the periodic PHR or the regular PHR is triggered in step 2320, the UE proceeds to step 2330 to generate and transmit a PHR for the reverse carrier triggered by the PHR. Since the PHR transmission may be performed only through the corresponding reverse carrier, for example, triggered PHRs may be transmitted at different time points.
- step 2330 the UE transmits the PHR, and then proceeds to step 2335 and checks whether the transmitted PHR is a PHR triggered by transmission output reduction. If so, the process proceeds to step 2340, and if the PHR triggered for reasons other than the reduction of the transmission output, the process proceeds to step 2350.
- step 2340 the terminal cancels the PHR transmission is complete.
- step 2345 the canceled PHRs are triggered again to be transmitted once again at the next transmission opportunity. This is because the PHRs are transmitted with a reduced transmission output, so transmission failures are likely to occur.
- the terminal proceeding to step 2350 drives the prohibit timer.
- the prohibit timer is to prevent the PHR from being transmitted too frequently and is driven every time the PHR is transmitted.
- the terminal does not trigger a periodic PHR or a regular PHR while the prohibit timer is driven.
- the PHR generated by the transmission output reduction does not perform the operation of driving the prohibit timer after the PHR is transmitted. This is because the main purpose of the prohibit timer is to prevent the occurrence of the periodic PHR or the regular PHRs frequently, so that the PHR by reducing the transmission output having a different importance from the conventional PHR is driven independently of the prohibit timer.
- the terminal drives only some of the carriers in an active state and others in an inactive state in order to reduce power consumption.
- the carrier activation and deactivation is controlled by a control message of the MAC layer transmitted by the base station.
- the MAC layer control message includes a predetermined bitmap and indicates the states of the remaining carriers except the primary carrier in the bitmap. Meanwhile, one carrier of the carriers is designated as a primary carrier, and the primary carrier has a characteristic of always being activated.
- the base station may change the primary carrier of the terminal as needed.
- the mapping relationship between the bits of the bitmap and the carrier may be set, for example, in a control message for establishing a carrier. For example, assuming that carrier 1, carrier 2, and carrier 3 are configured in the terminal, and carrier 1 is the primary carrier, the base station determines whether the carrier 2 corresponds to the bitmap in a control message for configuring carrier 2 and carrier 3 to the terminal. Corresponding to the number of bits (for example, the first bit), the carrier 3 may indicate the number of bits (for example, the second bit) of the bitmap.
- the base station When the primary carrier of the terminal is changed, the base station should indicate how many bits of the previous primary carrier corresponds to the bitmap.
- a set of carriers set in a terminal When a set of carriers set in a terminal is called a set carrier set, when the primary carrier is changed, it may be classified into a case in which both the old primary carrier and the new primary carrier belong to the set carrier set and otherwise. . Given that the primary carrier change is likely to be usually performed in terms of load balancing, it is expected that primary carrier changes belonging to the first type will be more frequent.
- the first type of primary carrier change is that the bit position used by the new primary carrier is available because both the old primary carrier and the new primary carrier are already established carriers.
- the bit position of the new primary carrier can be used as the bit position of the old primary carrier. For example, when the primary carrier is changed from carrier 1 to carrier 2, if there is already a bit position assigned to carrier 2, the terminal uses the bit position used by carrier 2 as the bit position of carrier 1.
- 24 is a flowchart illustrating a method of changing a primary carrier according to an embodiment of the present invention.
- the terminal receives a control message for changing a primary carrier from a base station.
- a control message for changing a primary carrier from a base station.
- carriers and cells are different concepts, they are often used in the 3GPP standard when it comes to carrier aggregation. In the present invention, the carrier and the cell are to be understood in the same context unless otherwise specified.
- the terminal changes the primary carrier according to the indication of the primary carrier change message.
- the UE checks whether the control message has information about a bit position of a previous primary carrier. If yes, the flow proceeds to step 2420 to map the indicated bit position to the previous primary carrier.
- the information on the bit position is information indicating the number of bits of the bitmap.
- step 2415 the UE checks the bit position of the carrier that has become the new primary carrier through the control message and sets the bit position of the identified carrier to the bit position of the previous primary carrier.
- FIG. 25 is a flowchart illustrating still another operation of a terminal in a method for reporting available transmission power according to an embodiment of the present invention.
- the terminal proposes a procedure for processing PHR of a plurality of carriers related to carrier aggregation.
- one terminal When a plurality of reverse carriers are integrated in one terminal and a PHR function is configured for each carrier, one terminal should check whether a PHR is generated for the plurality of carriers. As described above, whether or not PHR is generated is determined by a periodic timer and a path loss change amount. In terms of delivering the PHR to the base station in a timely manner, the periodic timer and the reference value of the path loss are set independently for each reverse carrier.
- the path loss per reverse carrier may not be large. Therefore, if it is determined whether PHR is triggered only for one selected reverse carrier among a plurality of reverse carriers, and if PHR is triggered for the selected reverse carrier, the terminal operation can be simplified if PHR is triggered together with PHR of all reverse carriers.
- the PHR is divided into a primary carrier PHR and a secondary carrier PHR.
- the PHR for secondary carrier is newly defined. Two bits not used may indicate which secondary carrier the PHR for a secondary carrier is.
- the PHR is a kind of MAC control element (CE) and includes a MAC subheader 2505 and a payload 2510.
- Information indicating that the corresponding MAC CE is PHR is inserted into the logical channel identifier field 2515 of the MAC subheader, and a power headroom (PH) is inserted into 6 bits 2530 of the payload.
- PH power headroom
- a logical channel identifier indicating a primary carrier PHR 2635 and a logical channel identifier indicating a secondary carrier PHR 2670 are respectively defined, and a MAC subheader ( By inserting the appropriate logical channel identifier in the logical channel identifier field of 2645, the primary carrier PHR 2635 and the secondary carrier PHR 2670 are distinguished.
- the first two bits 2620 of the payload 2610 of the PHR 2635 for the primary carrier are not used and the PH of the primary carrier is stored in the remaining six bits 2630 of the payload.
- the payload 2610 of the PHR 2635 for the primary carrier is composed of 2 bytes, and the first byte 2620 of the payload 2610 includes the primary carrier.
- the PH for PUSCH may be stored, and the PH for PUCCH may be stored in the second byte 2625.
- the first 2 bits 2660 of the payload 2650 of the secondary carrier PHR 2670 contain information indicating which secondary carrier the PHR is for, and the secondary 6 bits 2665 of the payload contain the secondary.
- the PH of the carrier is written.
- the secondary carriers PHR 2670 may store PHs of a plurality of secondary carriers.
- the identifier 2660 of the secondary carrier and the PHs 2665 of the secondary carrier may be stored for each byte of the payload 2650 of the secondary carrier PHR 2670.
- the size of the payload 2650 of the PHR 2670 of the secondary carrier is variable according to the number of PHs of the secondary carrier accommodated, it is necessary to explicitly indicate the size of the PHR 2670 for the secondary carrier.
- the size of the PHR 2670 for the secondary carrier may indicate its size using, for example, two unused bits 2475 and 2680 of the MAC subheader 2645.
- FIG. 27 is a flowchart illustrating a method for reporting available transmission power according to an embodiment of the present invention.
- the base station 2710 uses a predetermined control message for the terminal 2705.
- the PHR configuration information is transmitted to the CDMA (2715).
- the PHR configuration information includes a path loss change (dl-pathlossChange), a periodic PHR timer (periodicPHR-timer), a prohibit PHR timer (prohibitPHR-timer), a carrier component (CC) to determine whether PHR is triggered, and the secondary carrier PHR.
- At least one of an identifier of a secondary carrier (hereinafter, referred to as a secondary carrier identifier for PHR) 2660 to be used at 2670.
- the prohibit PHR timer (prohibitPHR-timer) is to prevent the occurrence of PHR too frequently, it is driven when the PHR is transmitted. Prohibit PHR is not triggered while the PHR timer is running.
- the CC to be determined whether or not PHR triggering is a CC (hereinafter, referred to as a triggering CC) used by the UE to determine whether to trigger PHR with reference to the path loss change.
- the triggering CC to be determined whether or not PHR triggering is a forward CC may be directly instructed by the base station or may be determined according to a method previously promised between the terminal and the base station.
- primary CC may be used to determine whether PHR triggering.
- Four secondary identifiers 2660 are defined, for example, from 0 to 3, and may be directly indicated for each secondary carrier or inferred from other information. For example, if another identifier for each carrier is allocated, the secondary carrier identifier for the PHR may be allocated in a predetermined manner in order of the size of the allocated identifier. Alternatively, the secondary carrier identifier for the PHR may be allocated in the order of the center frequency of the carrier, from high frequency to low frequency, or vice versa.
- step 2720 of FIG. 27 when the UE receives the PHR configuration information from the base station in step 2715, the UE determines whether to trigger PHR by referring to the PHR configuration information. The determination of whether the PHR is triggered is performed by referring to whether the path loss change of the forward carrier whose PHR triggering is determined exceeds a predetermined reference value, or whether the periodic timer has expired.
- the UE includes the PHR in the MAC PDU transmitted at the earliest time in step 2730 and transmits.
- the PHR includes a PHR for a primary carrier and a PHR for a secondary carrier.
- the secondary carrier PHR may be one or plural. If the PHs of all the secondary carriers are stored in one secondary carrier PHR, information indicating the size of the secondary carrier PHR is also stored in the MAC subheader of the secondary carrier PHR.
- the base station updates the PH for each carrier of the terminal to the value reported in step 2730 and refers to the future reverse scheduling.
- the carrier can often be understood to mean the same as the cell, the primary carrier can be understood as the primary cell, the secondary carrier can be understood as the secondary cell.
- FIG. 29 is a block diagram illustrating a configuration of a terminal according to an embodiment of the present invention.
- the terminal device of FIG. 29 includes a transceiver 2905, a controller 2910, a multiplexing and demultiplexing unit 2920, and a control message processing unit 2935. ) And various upper layer processing units 2925 and 2930.
- the transceiver 2905 receives data and a predetermined control signal through a forward carrier and transmits data and a predetermined control signal through a reverse carrier. When a plurality of carriers are set, the transceiver 2905 performs data transmission and reception and control signal transmission and reception to the plurality of carriers.
- the multiplexing and demultiplexing unit 2920 may multiplex the data generated by the upper layer processing units 2925 and 2930 or the control message processing unit 2935, or demultiplex the data received by the transmitting and receiving unit 2905 to appropriately apply the upper layer processing unit 2925. 2930 or the control message processor 2935.
- the multiplexing and demultiplexing unit 2920 also multiplexes the control message transmitted from the control unit 2910, for example, BSR or PHR, to the MAC PDU.
- control message processing unit 2935 processes the control message transmitted by the network and takes necessary actions.
- the control message processor 2935 transfers the carrier related information stored in the control message to the controller 2910.
- the upper layer processing units 2925 and 2930 may be configured for each service, and may process data generated from user services such as FTP or VoIP, and deliver the data to the multiplexing and demultiplexing unit 2920 or from the multiplexing and demultiplexing unit 2920. The delivered data is processed and delivered to the higher level service application.
- the control unit 2910 multiplexes the transmission / reception unit 2905 with the transmission / reception unit 2905 to analyze the scheduling command received through the transmission / reception unit 2905, for example, a reverse grant, and the like to perform reverse transmission with the appropriate transmission resource at an appropriate time.
- the demultiplexer 2920 is controlled.
- the control unit 2910 also generates scheduling information such as BSR or PHR at an appropriate time point and delivers the scheduling information to the multiplexing and demultiplexing unit 2920. That is, the controller 2910 controls BSR to be performed according to a predetermined method among the methods described in the first to third embodiments and the seventh embodiment. That is, the controller 2910 determines which buffer state table is used to generate the BSR when the condition for generating the BSR is satisfied.
- the control unit 2910 may perform logical channel prioritization at some point in time. Determine when to determine the BSR format and the BSR's buffer status.
- the controller 2910 controls the PHR to be performed according to a predetermined method among the methods described in the fourth to sixth, eighth and tenth embodiments. That is, the controller 2910 determines whether the available transmission power information for the PUSCH is triggered for each uplink carrier. The control unit 2910 also determines whether to accommodate the available transmit power information for the PUCCH in generating the PHR MAC CE for any reverse carrier. The controller 2910 also determines whether the PHR function is activated for any reverse carrier.
- the control unit 2910 may also determine whether to restart the PHR timers of the uplink carriers having the PHR function set upon receiving the uplink grant for uplink transmission.
- the controller 2910 may set the bit position of the new or previous primary carrier according to the primary carrier change control message received from the base station according to the primary carrier change method described in the ninth embodiment.
- FIG. 30 is a block diagram showing the configuration of a base station according to an embodiment of the present invention.
- the base station apparatus of FIG. 30 includes a transceiver 3005, a controller 3010, a multiplexing and demultiplexing unit 3020, a control message processing unit 3035, various upper layer processing units 3025 and 3030, and a scheduler. 3040.
- the transceiver 3005 receives data and a predetermined control signal through a reverse carrier and transmits data and a predetermined control signal through a forward carrier. When a plurality of carriers are set, the transceiver 3005 performs data transmission and reception and control signal transmission and reception to the plurality of carriers.
- the multiplexing and demultiplexing unit 3020 multiplexes data generated by the upper layer processing units 3025 and 3030 or the control message processing unit 3035, or demultiplexes the data received by the transmitting and receiving unit 3005 so that the appropriate upper layer processing unit 3025, 3030 or the control message processor 3035.
- the multiplexing and demultiplexing unit 3020 also demultiplexes a control message, for example, BSR or PHR, transmitted from the control unit 3010 in the MAC PDU to the control unit 3010.
- the control message processing unit 3035 generates a predetermined control message and transmits the generated control message to the multiplexing and demultiplexing unit 3020, or processes the control message delivered by the multiplexing and demultiplexing unit 3020.
- the control message processing unit 3020 may generate a control message for additionally setting a carrier to an arbitrary terminal and transmit the generated control message to the multiplexing and demultiplexing unit 3020.
- the upper layer processing units 3025 and 3030 may be configured for each specific terminal for each service, and may process data generated from user services such as FTP or VoIP, and deliver the data to the multiplexing and demultiplexing unit 3020 or multiplexing and demultiplexing.
- the multiplexer 3020 processes the data delivered to the service application of the upper layer.
- the controller 3010 also interprets scheduling information such as BSR and PHR to inform the scheduler 3040 of the buffer status of the terminal or the available transmission power.
- the BSR is controlled to be performed according to a predetermined method among the methods described in the first to third embodiments and the seventh embodiment. That is, the controller 3010 determines which buffer status table the received BSR refers to, and recognizes the amount of transmittable data stored in the terminal and the logical channel group in which the transmittable data is stored in the BSR, and the scheduler 3040. ).
- the controller 3010 controls the PHR to be performed according to a predetermined method among the methods described in the fourth to sixth, eighth, and tenth embodiments.
- the controller 3010 derives available transmission power information from the received PHR and informs the scheduler 3040 of this.
- the multiplexing and demultiplexing unit 3020 examines the subheader of the MAC PDU delivered by the transceiver 3005 and forwards it to the appropriate upper layer processing units 3025 and 3030.
- the multiplexing and demultiplexing units 3025 and 3030 transmit the received information to the controller 3010 when the BSR or the PHR is stored in the MAC PDU.
- the payload part receives the PHR MAC CE in which both the available transmission power information for the PUSCH and the available transmission power information for the PUCCH are stored.
- the demultiplexing is performed to the control unit 3010.
- the scheduler 3040 performs an operation of allocating transmission resources for each terminal and determining a transmission format in consideration of a buffer state, a channel condition, etc. of the terminal.
- the controller 3010 may transmit the primary carrier change control message to the terminal according to the primary carrier change method described in the ninth embodiment so that the terminal may set the bit position of the new or previous primary carrier.
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Claims (20)
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,상기 캐리어 집적에 의해 추가되는 역방향 캐리어에 대한 정보를 포함하는 제어 메시지를 기지국으로부터 수신하는 과정; 및상기 제어 메시지에 포함된 정보를 근거로 상기 기지국으로 버퍼 상태 보고를 위해 사용될 새로운 버퍼 상태 테이블을 결정하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 1 항에 있어서,상기 결정하는 과정은,상기 제어 메시지에 포함된 정보는 상기 추가되는 역방향 캐리어의 수를 포함하며, 상기 추가되는 역방향 캐리어의 수를 근거로 상기 새로운 버퍼 상태 테이블을 결정하는 과정을 더 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 1 항에 있어서,상기 결정하는 과정은,상기 제어 메시지에 포함된 정보는 최대 역방향 전송 속도를 계산하기 위한 정보를 포함하며, 상기 최대 역방향 전송 속도에 대응되게 상기 새로운 버퍼 상태 테이블을 결정하는 과정을 더 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 1 항에 있어서,상기 제어 메시지는 새로운 버퍼 상태 테이블을 지시하는 정보를 더 포함하는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,기지국으로부터 역방향 캐리어 설정을 지시하는 제어 메시지를 수신하여 새로이 사용될 버퍼 상태 테이블을 결정하는 과정; 및버퍼 상태 보고(BSR)가 트리거된 경우 상기 결정된 버퍼 상태 테이블의 식별자와 상기 BSR를 포함하는 MAC PDU를 생성하여 상기 기지국으로 전송하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 5 항에 있어서,상기 결정된 버퍼 상태 테이블의 식별자는 상기 MAC PDU에 수납된 적어도 하나의 MAC SDU의 서브 헤더에서 R(Reserved) 비트에 설정되는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,기지국으로부터 서브 프레임에 대한 최초 전송을 지시하는 역방향 그랜트를 수신하고, 연관된 순방향 캐리어들로부터 제어 채널을 수신하는 과정; 및버퍼 상태 보고가 트리거된 경우 상기 버퍼 상태 보고의 포맷과 버퍼 상태 값을 결정하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 7 항에 있어서,상기 기지국으로 전송하는 서브 프레임내 다수의 MAC PDU들 중 하나의 MAC PDU에 상기 버퍼 상태 보고가 포함되는 스케쥴링 정보를 처리하는 방법.
- 제 7 항에 있어서,상기 기지국으로 전송하는 서브 프레임에 대해 다수의 역방향 그랜트가 할당된 경우, 마지막 역방향 그랜트를 처리하면서 상기 버퍼 상태 보고를 생성하는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,역방향 그랜트를 수신한 후, 역방향 캐리어에 대한 데이터 채널 PHR의 트리거 여부를 판단하는 과정; 및데이터 채널 PHR이 트리거되고 상기 역방향 캐리어가 PCC(Primary Component Carrier)인 경우 제어 채널 PHR의 설정 여부에 따라 상기 제어 채널 PHR을 생성하여 상기 기지국으로 전송하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 10 항에 있어서,상기 제어 채널 PHR이 설정된 경우 상기 데이터 채널 PHR과 함께 상기 제어 채널 PHR을 생성하여 상기 기지국으로 생성하는 과정을 더 포함하는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,기지국으로부터 새로운 전송을 위한 업링크 자원을 할당 받는 과정; 및상기 새로운 전송을 위한 업링크 자원이 MAC 리셋이후 처음으로 할당된 업링크 자원인 경우, 주기적 PHR 타이머가 설정되어 있는 역방향 캐리어들의 상기 주기적 PHR 타이머를 구동시키는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,기지국으로부터 버퍼 상태 보고의 트리거를 위한 파라미터를 수신하여 상기 트리거를 활성화하는 과정;상기 트리거된 버퍼 상태 보고의 버퍼 상태 값이 기준 버퍼 상태 값을 만족하는 지 확인하는 과정; 및상기 버퍼 상태 값이 상기 기준 버퍼 상태 값을 만족하는 경우 미리 정해진 기준 트리거를 적용하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 13 항에 있어서,상기 미리 정해진 기준 트리거는 전송 양 기준 트리거인 스케쥴링 정보를 처리하는 방법.
- 제 13 항에 있어서,상기 미리 정해진 기준 트리거는 전송 비율 기준 트리거인 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,역방향 전송 시 전송 출력 축소의 발생 여부를 판단하는 과정; 및상기 전송 출력 축소가 발생될 경우, 역방향 캐리어들 중에서 PHR이 설정된 역방향 캐리어들의 PHR을 트리거하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 캐리어 집적을 지원하는 이동 통신 시스템의 단말에서 스케쥴링 정보를 처리하는 방법에 있어서,기지국으로부터 PHR 설정 정보를 포함하는 제어 메시지를 수신하여 PHR 트리거링 여부를 판단하는 과정; 및상기 PHR이 트리거되면, 프라이머리 캐리어용 PHR과 세컨더리 캐리어용 PHR를 포함하는 PDU를 상기 기지국으로 전송하는 과정을 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 17 항에 있어서,상기 제어 메시지는 경로 손실 변화(dl-pathlossChange), 주기적 PHR 타이머(periodicPHR-timer), 금지 PHR 타이머(prohibitPHR-timer), PHR 트리거링 여부가 판단될 캐리어 콤포넌트(CC), PHR용 세컨더리 캐리어 식별자 중 적어도 하나를 포함하는 스케쥴링 정보를 처리하는 방법.
- 제 17 항에 있어서,상기 세컨더리 캐리어용 PHR은 하나 또는 복수 개인 스케쥴링 정보를 처리하는 방법.
- 제 17 항에 있어서,하나의 세컨더리 캐리어용 PHR에 모든 세컨더리 캐리어의 PH를 수납한다면 상기 세컨더리 캐리어용 PHR의 MAC 서브 헤더에는 상기 세컨더리 캐리어용 PHR의 크기를 지시하는 정보가 포함되는 스케쥴링 정보를 처리하는 방법.
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CN105577345A (zh) | 2016-05-11 |
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EP3606256A1 (en) | 2020-02-05 |
JP5940687B2 (ja) | 2016-06-29 |
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EP2557880A2 (en) | 2013-02-13 |
US10660086B2 (en) | 2020-05-19 |
US9042320B2 (en) | 2015-05-26 |
EP3442294B1 (en) | 2019-10-30 |
CN102934505B (zh) | 2016-03-23 |
US20200137754A1 (en) | 2020-04-30 |
CN102934505A (zh) | 2013-02-13 |
EP3606256B1 (en) | 2021-06-02 |
US11368953B2 (en) | 2022-06-21 |
WO2011126311A3 (ko) | 2012-01-19 |
US20150230248A1 (en) | 2015-08-13 |
EP2557880B1 (en) | 2018-10-31 |
CN105743628A (zh) | 2016-07-06 |
JP2015065706A (ja) | 2015-04-09 |
CN105743628B (zh) | 2019-11-29 |
EP3442294A1 (en) | 2019-02-13 |
KR20110112179A (ko) | 2011-10-12 |
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