method and apparatus for transmitting or receiving a signal in a wireless communication system

专利摘要:
The present invention relates to a method for receiving downlink control information from a terminal in a wireless communication system according to an embodiment of the present invention comprising the steps of: receiving information about a reference subcarrier spacing (scs) between a plurality of scs numerologies; receive downlink control information via a common terminal group physical downlink control channel (pdcch); and obtaining information about a partition format from downlink control information, where downlink control information indicates the partition format based on the reference scs, and when the terminal scs is different from the reference scs, The terminal can convert the partition format of the reference scs according to the terminal scs.
公开号:BR112019003170A2
申请号:R112019003170
申请日:2018-03-23
公开日:2019-10-01
发明作者:Seo Inkwon；Jo Soonki；Yi Yunjung
申请人:Lg Electronics Inc；
IPC主号:

专利说明:

“METHOD AND APPARATUS FOR TRANSMITTING OR RECEIVING SIGNAL IN A WIRELESS COMMUNICATION SYSTEM” [Technical field] [001] The present invention relates to a wireless communication system and, more particularly, to a method and apparatus for transmitting or receiving downlink control (DL) information in a wireless communication system.
[Foundation Technique] [002] First, the existing LTE / LTE-A 3GPP system will be briefly described. Referring to FIG. 1, the UE performs an initial cell search (S101). In the initial cell search process, the UE receives a Primary Synchronization Channel (P-SCH) and a Secondary Synchronization Channel (S-SCH) from a base station, performs downlink synchronization with the BS and acquires information as an ID cell. The UE then acquires system information (for example, MIB) through a PBCH (Physical Broadcast Channel). The UE can receive the DL RS (Downlink Reference Signal) and check the status of the downlink channel.
[003] After the initial cell search, the UE can acquire more detailed system information (for example, SIBs) by receiving a physical downlink control channel (PDCCH) and a physical downlink control channel (PDSCH) programmed by the PDCCH (S102).
[004] The UE can perform a random access procedure for uplink synchronization. The UE transmits a preamble (for example, Msg1) through a physical random access channel (PRACH) (S103), and receives a response message (for example, Msg2) to the preamble via PDCCH and PDSCH corresponding to the PDCCH. In the case of contention-based random access, a contention resolution procedure such as additional PRACH transmission (S105) and PDCCH / PDSCH reception (S106) can be
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2/67 executed.
[005] Then, the UE can perform PDCCH / PDSCH (S107) reception and transmission of Physical Uplink Shared Channel (PUSCH) / Physical Uplink Control Channel (PUCCH) (S108) as a signal transmission procedure general uplink / downlink. The UE can transmit UCI (Uplink Control Information) to the BS. The UCI may include HARQ ACK / NACK (Hybrid Automatic Repeat Confirmation / Negative ACK), SR (Programming Request), CQI (Channel Quality Indicator), PMI (Pre-Coding Matrix Indicator) and / or RI, etc.
[Disclosure] [Technical Problem] [006] An object of the present invention designed to solve the problem remains in a method and apparatus to more effectively and accurately indicate a partition format through downlink control information (DL) in a wireless communication system to support multiple subcarrier spacing (SCS).
[007] It should be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide a further explanation of the invention as claimed.
[Technical Solution] [008] The object of the present invention can be achieved by providing a method for receiving downlink control information (DL) by a user equipment (UE) in a wireless communication system, the method including receiving information about reference subcarrier (SCS) spacing between a plurality of SCS numerologies, receive DL control information through a common downlink control channel (PDCCH) and acquire information about a
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3/67 partition format, from DL control information, where DL control information indicates the partition format based on the reference SCS, and where, when the SCS of the UE is different from the SCS of reference, the UE converts a partition format of the reference SCS according to the UE SCS.
[009] In another aspect of the present invention, user equipment (UE) is provided to receive downlink control (DL) information, including a receiver, and a processor configured to control the receiver to receive information on sub carrier spacing. reference (SCS) among a plurality of SCS numerologies, receiving DL control information through a common physical downlink control channel (PDCCH) and acquiring information about a partition format, from DL control information, in that the DL control information indicates the partition format based on the reference SCS, and where, when the SCS of the UE is different from the reference SCS, the processor converts a partition format of the reference SCS according to the SCS of the UE.
[010] In another aspect of the present invention, provided in this document, it is a method for transmitting downlink control (DL) information by a base station (BS) in a wireless communication system, including the transmission of information in spacing reference sub carrier (SCS) between a plurality of SCS numerologies, generate DL control information including information on a partition format, and transmit DL control information to an UE group including the UE through a control channel physical downlink (PDCCH) group UE, where, even if the UE SCS is different from the reference SCS, BS notifies the UE about the partition format based on the reference SCS.
[011] In another aspect of the present invention, a base station (BS) is provided here to perform the method for transmitting control information from
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DL mentioned above.
[012] Information about the reference SCS can be received via upper layer signaling.
[013] The time duration of 1 partition can be variable depending on the SCS, and the reference SCS can be configured to be equal to or less than the SCS of the UE such that the time duration of 1 partition based on the SCS reference time is equal to or greater than the duration of 1 partition based on the SCS of the UE.
[014] When the SCS of the UE is M times the reference SCS, the UE can interpret 1 partition based on the reference SCS as M contiguous partitions based on the SCS of the UE.
[015] The UE can determine, based on information about the partition format, whether each of a plurality of symbols included in a corresponding partition corresponds to downlink (D), uplink (U) or flexible (X); and where, when the SCS of the UE is M times the reference SCS, the UE can interpret a D, U or X symbol based on the reference SCS as the number M of D, U or X symbols based on the SCS of the HUH.
[016] Information about the partition format can indicate at least one of the partition formation combinations configured in the UE.
[017] The UE can be configured with a plurality of frequency bands and each combination of partition formats can be a combination of a plurality of partition formats of the plurality of frequency bands.
[018] The combination of each partition format is a combination of a partition format for a DL frequency band and a partition format for a UL frequency band. Alternatively, where the combination of each partition format can be a combination of a partition format for a new radio access technology (NR) frequency band and a
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5/67 partition for a long-term evolution frequency (LTE) frequency band.
[019] The partition formation combinations configured in the UE can be received via upper layer signaling and can be a subset of a plurality of partition format combinations supported in the wireless communications system.
[Advantageous Effects] [020] According to one embodiment of the present invention, the reference subcarrier spacing (SCS) is configured in a wireless communication system in which several SCS are supported to accurately interpret a partition format and a partition format can be flagged UE group normally based on the reference SCS and therefore a payload size of the physical downlink control channel (PDCCH) can be reduced and the overhead of the PDCCH can be reduced compared to the case where a partition format is indicated for each separate SCS.
[021] It will be appreciated by those skilled in the art that the effects that can be achieved with the present invention are not limited to what was particularly described here above and other advantages of the present invention will be more clearly understood from the detailed description that follows together with the attached drawings [Description of Drawings] [022] FIG. 1 illustrates the physical channels used in an LTE / LTE-A 3GPP system and a general method for signal transmission using the physical channels.
[023] FIG. 2 illustrates 1 partition based on 15 kHz subcarrier spacing (SCS) and 1 partition based on 60 kHz SCS.
[024] FIG. 3 illustrates combinations of partition formats according to an embodiment of the present invention.
[025] FIG. 4 illustrates combinations of partition formats according to
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6/67 another embodiment of the present invention.
[026] FIGS. 5 and 6 illustrate combinations of partition formats according to another embodiment of the present invention.
[027] FIG. 7 illustrates a partition format combination according to an embodiment of the present invention.
[028] FIG. 8 illustrates partition format patterns according to an embodiment of the present invention.
[029] FIG. 9 illustrates the reserved allocation of resources for a common physical downlink control channel (PDCCH) according to an embodiment of the present invention.
[030] FIG. 10 illustrates a GSS deployed in a CSS according to an embodiment of the present invention.
[031] FIG. 11 illustrates GSS candidates having a fixed position in a CSS according to an embodiment of the present invention.
[032] FIGs. 12 and 13 illustrate multiple CC partition patterns according to an embodiment of the present invention.
[033] FIG. 14 illustrates multiple CC partition patterns according to another embodiment of the present invention.
[034] FIG. 15 illustrates a flow of a method for transmitting and receiving downlink control information (DCI) according to an embodiment of the present invention.
[035] FIG. 16 illustrates a base station (BS) and user equipment (UE) according to one embodiment of the present invention [Invention Mode] [036] The following description of embodiments of the present invention can apply to various access systems without wire including CDMA (code division multiple access), FDMA (frequency division multiple access), TDMA (access
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7/67 multiple by time division), OFDMA (orthogonal frequency division multiple access), SC-FDMA (single carrier frequency division multiple access) and the like. CDMA can be implemented with such a radio technology as UTRA (universal terrestrial radio access), CDMA 2000 and the like. TDMA can be implemented with radio technology such as GSM / GPRS / EDGE (Global System for Mobile Communications) / General Radio Packet Service / Enhanced Data Rates for GSM Evolution. OFDMA can be implemented with radio technology such as IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20, UTRA (UTRA Evolved), etc. UTRA is part of UMTS (Universal System for Mobile Telecommunications). LTE (long term evolution) 3GPP (3rd Generation Partnership Project) is part of E-UMTS (Evolved UMTS) that uses E-UTRA. LTE 3GPP adopts OFDMA in the downlink and adopts SC-FDMA in the uplink. LTE-A (LTE-Avannçada) is an evolved version of LTE 3GPP.
[037] For clarity, the description that follows refers mainly to the LTE 3GPP system or to the LTE-A 3GPP system, whereby the technical idea of the present invention may be not limited. The specific terminologies used in the following description are provided to help understand the present invention and the use of the terminologies can be modified to a different form within the scope of the technical idea of the present invention.
[038] As much as possible, communication devices have required high communication capacity and therefore there has been a need for improved mobile broadband communication (eMBB) compared to radio access technology (RAT) in a communication system state-of-the-art recently discussed. In addition, massive machine-type communications (mMTC) to connect a plurality of devices and objects to provide various services at any time and anywhere are also one of the factors to be considered in next generation communication. Furthermore, in
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8/67 consideration to service! user equipment (UE) sensitive to reliability and latency, ultra-reliable and low latency communication (URLLC) has been discussed for a next generation communication system.
[039] Thus, a new RAT that considers eMBB, mMTC, URLCC and so on has been discussed for next generation wireless communication.
[040] Some LTE / LTE-A operations and configurations that are not at odds with the New RAT project can also be applied to the new RAT. For convenience, the new RAT can be called 5G mobile communication.
<NR Frame Structure and Physical Resource [041] In an NR system, downlink (DL) and uplink (UL) transmission can be performed through frames lasting 10 ms and each frame can include 10 subframes. Accordingly, 1 subframe can correspond to 1 ms. Each frame can be divided into two half frames.
[042] 1 subframe may include Nsímb ^{subquadrop partipSo} X = Nsimb NPartição ^{subframe 'p} contiguous OFDM symbols. NSímb ^partiçã0 represents the number of symbols per partition, μ represents OFDM numerology and N _P ^subframe qj represents the number of partitions per subframe in relation to the corresponding μ. In NR, several OFDM numerologies shown in Table 1 below can be supported.
[Table 1]
μ Af = 2 ^μ 15 kHz] Cyclic prefix 0 15 Normal 1 30 Normal 2 60 Normal, extended 3 120 Normal 4 240 Normal
[043] In the table above, Af refers to subcarrier spacing (SCS). μ and cyclic prefix with respect to a portion of bandwidth of the DL carrier (BWP) and μ and cyclic prefix with respect to a UL carrier BWP can be configured for a UE via UL signaling.
[044] Table 2 below shows the number of Nsímb symbol ^partitions per
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9/67 partition, the number of ^frame partitions, ^J of symbols per frame and the number of ^sub -frame partitions ^{, J} of partitions per sub-frame in relation to each SCS in the case of normal PLC.
[Table 2]
μ ..partition * simb ..frame, μ v partition ..subframe, μ v partition 0 14 10 1 1 14 20 2 2 14 40 4 3 14 80 8 4 14 160 16 5 14 320 32
[045] Table 3 below shows the number N _S IMB ^partiçã0 symbols by partition, Npartição ^{frame number, J} partitions per frame and Npartição number ^{subframe, J} partitions per subframe for each SCS in the case of extended PC .
[Table 3]
μ ..partition ^ simb ..frame ^ v partition ..subframe, μ v partition 2 12 40 4
[046] As such, in an NR system, the number of partitions included in 1 subframe can vary depending on the spacing of the subcarrier (SCS). The OFDM symbols included in each partition can match any of D (DL), U (UL) and X (flexible). DL transmission can be performed on a D or X symbol and UL transmission can be performed on a U or X symbol. A flexible resource (for example, symbol X) can also be referred to as a Reserved resource, Another resource or a Unknown resource.
[047] In NR, a resource block (RB) can correspond to 12 subcarriers in the frequency domain. An RB can include a plurality of OFDM symbols. A resource element (RE) can correspond to 1 subcarrier and 1 OFDM symbol. Thus, 12 REs can be present in 1 OFDM symbol in 1 RB.
[048] A carrier BWP can be defined as a set of contiguous physical resource blocks (PRBs). The carrier BWP can also be simply referred to as a BWP A maximum of 4 BWPs can be
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10/67 configured for each UL / DL link in 1 UE. Even if multiple BWPs are configured, 1 BWP can be activated for a specified period of time. However, when a supplemental uplink (SOUTH) is configured in a UE, 4 BWPs can be additionally configured for the SOUTH and 1 BWP can be activated for a certain period of time. A UE cannot be expected to receive a PDSCH, a PDCCH, a channel status information reference signal (CSI-RS) or a tracking reference signal (TRS) outside the activated BWP DL. In addition, the UE cannot be expected to receive a PUSCH or PUCCH from the activated BWP UL.
Control Channel NR DL>
[049] In an NR system, an NR transmission system, a control channel transmission unit can be defined as a group of resource elements (REG) and / or a control channel element (CCE), etc. .
[050] A REG can correspond to 1 OFDM symbol in the time domain and can correspond to 1 PRB in the frequency domain. In addition, 1 CCE can correspond to 6 REGs.
[051] A set of control features (CORESET) and a search space (SS) are briefly described now. CORESET can be a set of features for transmitting control signals and the search space can be aggregation of control channel candidates to perform blind detection. The search space can be configured for CORESET. For example, when a search space is defined in a CORESET, a CORESET for a common search space (CSS) and a CORESET for a specific UE search space (USS) can be configured. As another example, a plurality of search spaces can be defined in a CORESET. For example, CSS and USS can be configured for the same CORESET. In the following example, the CSS can refer to a CORESET with a CSS configured for that purpose and the USS can refer to
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11/67 refer to a CORESET with a USS configured for that purpose, or something similar.
[052] A base station can signal information about a CORESET to a UE. For example, a CORESET configuration for each CORESET and time duration (for example, symbol 1/2/3) of the corresponding CORESET can be signaled. When interleaving to distribute a CCE for 1 CORESET symbol is applied, 2 or 6 REGs can be grouped. The grouping of 2 or 6 REGs can be performed in 2 CORESET symbols and the time-first mapping can be applied. The grouping of 3 or 6 REGs can be performed on 3 CORESET symbols and the time-first mapping can be applied. When REG grouping is performed, the UE can assume the same pre-coding in relation to a grouping aggregation unit.
Partition Format clause [053] A partition type and operating method of a UE when a guard period (GP) is maintained or changed are now described. In addition, a method for handling the partition type indication when the numerology of a partition type is changed and the methods for indicating reserved resources are described below. A partition type can be referred to as a partition format.
1. Partition Type Indication [054] A UE can receive information about a partition type. Partition type information can indicate a partition type and can include information about, for example, a downlink pilot time partition (DwPTS), an uplink pilot time partition (UpPTS), a guard period (GP ) and a reserved feature.
[055] Information about the type of partition can be transmitted periodically or aperiodically. If the received partition type indication information is applied, this can be determined by the UE or can be
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12/67 enforced.
[056] For example, information about the partition type can be received via a PDCCH. For example, information about the partition type can be received via a common PDCCH or it can also be received through specific UE control information (for example, DCI).
[057] The partition type information received through the common PDCCH can be control information to collectively indicate a partition type for a specific group of UEs or all UEs in a cell. The partition type information received through the UE-specific PDCCH can be control information, indicating a partition type for each UE.
2. Guard Period (GP) (1) Partition-based GP, all configured in DL or UL [058] A GP can be defined according to an end position of a DwPTS and an initial position of an UpPTS.
[059] The GP can be positioned after DwPTS. The final position of the DwPTS can be transmitted to a UE through a common PDCCH. For example, the UE can calculate the GP based on the final transmitted position of the DwPTS, and the UpPTS and the UL partition on which the transmission is to be performed. Separately, the GP indication can be signaled to the UE.
[060] The GP can be positioned before the UpPTS. The UE can receive information about an initial position of the UpPTS through the common PDCCH. The UE can use the starting position of the UpPTS as a final position of the GP without change or the UE can determine the final position of the GP based on the starting position of the UpPTS.
[061] The GP can be present only in one partition or it can be present between partitions. The position and duration of the GP may not be limited. It may be possible for the GP to be present between partitions when a partition
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DL and a UL partition are contiguously present. For example, the GP can be present between a DL partition and an UL partition.
[062] A method for forming a GP for each UE or for each UE group can be configured. The GP configuration can be common to the cell or can be predefined.
[063] Each EU or EU group can be configured with a GP, in which case more or less cell-specific GPs can be configured than flagged GPs for each EU or EU group. For example, when the number of UE GPs is less than common group or cell specific GPs, an additional feature can be used as a GP according to the dynamic indication and, when the number of UE GPs is greater than specific GPs cell or group common, an additional GP can be formed according to a predetermined rule.
(i) When GP is kept constant [064] A GP of a UE can be kept constant and may not be affected by a common PDCCH after the GP has been configured once. For example, a common cell or group GP transmitted in a system information block (SIB) or similar cannot be changed by a common PDCCH. In addition, the indication of a GP in the common PDCCH can be omitted.
[065] For example, when a GP has 5 symbols and a partition has 14 symbols, D, U, or reserved in relation to 9 symbols can be indicated. In addition, the GP can be configured for each subframe or for each set of partitions. The GP configuration can be provided as a fallback configuration. For example, the GP configured in fallback can always be assumed in relation to a common PDCCH. Fixed DL, UL, GP or reserved, configured in fallback, can be assumed and, thus, the corresponding indication can be omitted from the common PDCCH.
(ii) When GP is Modifiable by Common PDCCH
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14/67 [066] A GP of an UE can be modified by a common PDCCH. There may be no problem when the UE normally receives the common PDCCH, but there may be a problem in terms of GP configuration when the common PDCCH is not able to be received.
[067] Thus, a network needs to notify the UE about a minimum GP and a maximum GP supported by a cell. The minimum GP can be set to not be changed by the common PDCCH. For example, the minimum GP can be 0.
The. Fallback Operation When Common PDCCH is Lost [068] When determining that the partition type indication is not received by the UE or is not transmitted, the UE can maintain a most recently indicated partition type.
[069] In addition, when a specific partition type is preconfigured for the UE via semi-static signaling and the UE does not indicate the partition type or is unable to receive the partition type indication, a preconfigured partition type via semi-static signage can be used.
[070] GPs of the best / worst cases, used for fallback, can be defined. When a common PDCCH is set to indicate the best GP, a GP flagged for fallback can also be configured as the best GP. When the common PDCCH is set to indicate the worst GP, a GP flagged for fallback can also be configured as the worst GP [071] A GP of the best / worst case GP, which is applied for fallback, can be predefined or can be configured over a network. This may be necessary to define a UE operation when the fallback configuration is applied.
(2) When All UEs in Cell use the same GP [072] An environment in which all UEs in a cell use the same GP can be considered. A size of a DwPTS in which a UE receives a
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15/67 signal and an UpPTS size in which the UE transmits a signal can be the same for all UEs or it can be different for the UEs.
[073] When a DwPTS / UpPTS size is different for each UE, a PTS of each UE can be configured to be sufficiently placed in a partition type indicated by the PTS. For example, even if a DwPTS / UpPTS size is different for each UE, the DwPTS / UpPTS size of all UEs can be a size of a PTS in which UL / DL transmission and reception are enabled without change in a UE - commonly indicated partition type group. Alternatively, in reality, the size of DwPTS / UpPTS of all UEs can be the same (3) When GP is Different for each UE [074] An environment in which all the UEs in a cell are able to use different GPs can be considered. A size of a DwPTS in which a UE receives a signal and a size of an UpPTS in which the UE transmits a signal can be the same for all UEs or can be different for each UE.
[075] When notifying UEs about GP information via a common PDCCH, a network can configure the final DwPTS positions of all UEs as being the same. For example, a DwPTS end position can be the last point, the first point, or the intermediate point between the DwPTS end points of the UEs in a cell.
(I) When the last end point of the DwPTS is indicated [076] The end position of the DwPTS indicated by the network can be the last point between the end points of the DwPTSs of the UEs in a cell. Consequently, a final position of a DwPTS of a specific UE may be earlier than the final position of the DwPTS indicated through the common PDCCH. In this case, the UE can first terminate DL reception and, therefore, can transmit UL data for a guaranteed period of time or can transmit UL data only on an UpPTS.
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16/67 (ii) When the DwPTS Previous End Point is Indicated [077] The DwPTS end position indicated by the network can be the first point between the end points of the DwPTSs of the UEs in a cell. Consequently, a final position of a DwPTS of a specific UE can be later than the final position of the DwPTS indicated through the common PDCCH. In this case, when an UE's UpPTS start position is within a GP, the corresponding UE can transmit an UpPTS on the UL without change and, when the UpPTS start position is not within the GP, the UE can shorten the UpPTS and transmit the UpPTS on the UL or you can skip the UL transmission on the corresponding UpPTS.
(ill) When the end position of the average DwPTS is indicated [078] The end position of the DwPTS indicated by the network can be a midpoint between the end points of the DwPTSs of the UEs in a cell. Consequently, a final position of a DwPTS of a specific UE can be later or earlier than the final position of the DwPTS indicated through the common PDCCH. In consideration of this situation, two types of UpPTS can be defined for a short UpPTS and a long UpPTS and the UE can prepare the transmission in relation to two types of UpPTS.
3. Handling Different Numerologies and Partition Sizes [079] When the numerology of a DwPTS, an UpPTS or similar, which is transmitted and received by a UE, is changed, a partition size can also be changed. According to whether a partition type indicated via a common PDCCH is indicated based on the numerology that is currently used by the UE or is indicated based on the reference numerology, an UE operation and a used partition can be changed .
[080] For example, reference numerology as a reference for indicating a partition type can be defined / configured. When the partition type is indicated based on the reference numerology, the UE can change and
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17/67 interpret the type of partition indicated according to the numerology used by the UE. The UE can change a partition size indicated based on the reference numerology by the common PDCCH to a partition size corresponding to the numerology used by the UE and can apply the changed partition size.
[081] As another example, when a network indicates a partition type, the network can indicate a partition type according to the numerology used by the UE. In this case, the UE can apply the partition type indicated by the network without alteration instead of calculating a partition size separately.
4. Periodic Resource Configuration [082] Among the resources needed to maintain a UE's connection to a network, there may be resources that are not clearly defined or a partition type of which is not defined. To use these resources, the network can signal a configuration of corresponding resources using a common PDCCH or basically define a static configuration regarding the use of the corresponding resources.
(I) CSI-RS [083] To receive a CSI-RS by the UE, the following methods can be considered.
(i) For example, the UE can be set to always receive a periodic CSI-RS. Without separate indication for receiving CSI-RS, the UE can assume that the periodic CSI-RS is always transmitted over a network and can operate.
(II) As another example, the UE can pre-know the candidate resources on which a periodic CSI-RS is to be transmitted and the network can notify the UE on whether a CSI-RS is actually transmitted to a corresponding resource via the common PDCCH . In this case, the load can be reduced compared to the case where the UE always receives the CSI-RS, but the UE needs to properly receive the common PDCCH to receive the CSI-RS.
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18/67 [084] The network can also configure methods (i) and (ii) according to a channel situation.
[085] For example, CSI-RS can be classified into two types. The network can distinguish between a guaranteed CSI-RS in which transmission is ensured and a potential CSI-RS in which transmission must be enabled and can transmit a CSI-RS configuration. The guaranteed CSI-RS can always be transmitted without indication via a common PDCCH and the transmission of the potential CSI-RS can be activated via a common PDCCH or other control signals.
[086] The guaranteed CSI-RS can be used for periodic CSI reporting and the potential CSI-RS can also be used for an aperiodic CSI reporting that is triggered as needed.
[087] Both the guaranteed CSI-RS and the potential CSI-RS can be used to measure periodic / aperiodic CSI.
[088] Alternatively, the UE can selectively use the two types of CSIRSs as appropriate.
(2) Grand-Free Resource [089] In NR, a concession-free resource in which a UE performs UL transmission without receiving DCI corresponding to the UL concession can be configured.
[090] For example, there can be a always free concession resource that is always used as a free concession resource and a flexible free concession resource that is configured as a free concession resource according to the dynamic indication through a PDCCH common.
[091] Even if the UE does not receive an indication of a flexible resource, the UE can use the resource always free of concession.
[092] For example, the resource always free of concession can help the flexible resource free of concession.
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19/67 [093] In a state where the UE pre-knows candidates from all grant-free resources, the network can indicate the grant-free resource that must be used by the corresponding UE through a common PDCCH. In this case, by properly receiving the common PDCCH, there may be a limit to the extent that the UE is able to use the concession-free resource, but the concession-free resource in a system can be minimized.
[094] The network can determine an EU group that is able to attempt to access each concession-free resource and can also notify only the corresponding group about the concession-free resource through the common PDCCH. In this case, the common PDCCH may include identification information in UE (s) that is able to access the corresponding concession-free resource.
[095] The UE that is able to access the corresponding free concession resource can be determined according to the priority. For example, the priority can be determined based on a failure rate in the number of access attempts or it can be determined based on the urgent size / degree of UL data to be transmitted.
[096] This method for configuring permanent (or fixed) / flexible resources can also be applied to a semi-static resource, such as a radio resource management reference signal resource (RRM-RS), a random access channel resource (RACH) and a sync signal blocking (SS) feature.
[097] More typically, in the case of RRM-RS, a fixed resource can be used for measuring neighboring cells and a flexible resource can be used for measuring service cells. The transmit / receive points (TRPs) can exchange fixed resource configurations with each other and can configure the exchanged configurations for a UE.
[098] The fixed resource can be configured with a longer period than
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20/67 the flexible feature and the period of the fixed feature can influence the delay / accuracy of the measurement of the neighboring cell. In relation to a neighboring cell with an excellent measurement result equal to or greater than a limit value, the UE can be configured to perform the measurement on the flexible feature of the neighboring cell. To perform the measurement on the flexible feature of the neighboring cell, the UE can read a common PDCCH from the neighboring cell. For example, a service cell can signal information about a common PDCCH configuration of the neighboring cell and information about a method for transmission such as a period for the UE or the neighboring cell to broadcast the corresponding information through a SIB or the like.
[099] In addition, the neighbor cell measurement report using the UE using the flexible feature can be triggered by a network. For example, flexible features can be used additionally only in aperiodic RRM reports triggered by the network.
<Summary of Partition Type Indication and Additional Proposals>
[0100] Additional proposals, in addition to the descriptions above, are described below.
[0101] To design a common group PDCCH for partition type indication, potential differences in NR compared to improvements in TDD LTE for DL-UL interference management and traffic adaptation (LTE elMTA) need to be considered. For example, it may be necessary to consider that different lengths of GP are configured for the respective UEs in NR. Such consideration may be more important when different UEs use different numerologies or are related to different usage scenarios. In addition, it may be necessary to consider the indication of a partition structure in an NR network that provides multiple numerologies.
[0102] It may also be necessary to consider a relationship between a semi-static configuration and an indication of the type of dynamic partition and, for
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21/67 example, dynamic indication can replace the semi-static configuration for measurement for a more flexible design of an NR system than LTE.
1. EU specific GP configuration [0103] In an unpaired spectrum in which UL and DL are used in a TDM manner, it may be general to assume that a network operates on any one of UL and DL at once regardless of a numerology used.
[0104] In an LTE system, a specific GP cell length can be configured for all UEs. However, it can be inefficient to set the same GP length for all UEs in a cell in the NR system. For example, when a GP length is configured as 2 symbols based on the numerology corresponding to the 15 kHz SCS, the corresponding GP length can correspond to 8 symbols in numerology corresponding to the 60 kHz SCS. As such, the GP length corresponding to 8 symbols can be a longer period of time than a GP length which is really necessary for a UE operating on the 60 kHz SCS and a radio resource can be wasted.
[0105] In consideration, different propagation delays, different numerologies and / or different QoS requirements, a UE specific GP configuration may be more appropriate than a common cell / UE specific GP configuration in NR. To use a specific UE GP, a maximum GP supported by a network can be signaled to a UE. In addition, the UE specific GP can be determined and flagged.
[0106] As such, the NR can support an EU specific GP configuration.
2. UE operation according to Partition Type [0107] When the partition type indication is provided, a UE can determine a DL symbol, UL symbol and / or other symbols (for example,
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22/67 flexible symbols) from the partition type indication. Detailed contents in the partition type indication may indicate, for example, one of the predefined partition patterns, DL / UL bitmap and / or DwPTS and UpPTS lengths, but are not limited to them. To indicate a suitable partition type, it may be necessary to define the treatment of different lengths of GP.
[0108] In signaling a DL portion (resource) and a UL portion (resource) to a common group PDCCH, two approaches can be widely considered.
(i) A first method is to indicate the base case for the DL / UL portions by a network. For example, the DL / UL portions can be indicated according to the minimum GP supported by the network. In this case, a UE with a GP length greater than the minimum GP can determine where an additional required GP is positioned, based on the indicated partition structure.
(ii) A second method is to indicate the worst case for the DL / UL portions by a network. For example, the DL / UL portions can be indicated according to the maximum GP supported by the network. In this case, separate mechanisms for using other resources (for example, flexible) indicated by the partition indication can be used for DL or UL for a UE with a GP less than the maximum GP.
[0109] In addition, it may be necessary to determine where a GP indicated by a partition type is positioned in relation to UEs with different GP lengths.
[0110] For example, a UE can assume that a GP is always finalized after the DL portion. When partition 1 is dedicated to DL and partition 2 positioned after partition 1 is dedicated to UL, the GP can be positioned at the beginning of partition 2 dedicated to UL. When the minimum GP is indicated according to the partition type indication, an UE with a GP greater than the minimum GP can reduce the UL portion to ensure additional GP.
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23/67 [0111] As another example, a UE can assume that a GP is always positioned before starting the UL portion. When partition 1 is dedicated to DL and partition 2 is dedicated to UL, the GP can be positioned on a DL partition. When the minimum GP is indicated by the partition type indication, a UE with a GP greater than the minimum GP can reduce the DL portion to ensure additional GP.
[0112] Alternatively, a GP can be generated only by dynamic programming. For example, a UE can create a GP between the end of DL reception (for example, end of a control channel, end of DL data or end of measurement) and the beginning of UL transmission. However, this method can complicate an UE operation. Therefore, it may be more desirable to determine the insertion of a GP at the end of DL or beginning of UL.
[0113] Based on the above discussion, it may be necessary to determine whether a partition structure indicated by a common PDCCH is formed, assuming the best GP case or the worst GP case, which is supported by a network. In addition, the GP can be positioned after the DL portion or before the UL portion.
[0114] 3. Treatment of Different Numerologies and Different Partition Sizes [0115] A partition size can be related to numerology. When the DL or UL numerology is changed, a real effect can be changed depending on a relationship between numerology used in the partition type indication and numerology used in the control / data transmission. The common PDCCH can indicate a partition type and the numerology used as a reference for the partition type indication can be important for a UE.
[0116] For example, the partition type indication can be transmitted based on the reference numerology. Based on the reference numerology, the UE can interpret the indicated partition type as UE numerology and can estimate an appropriate partition size, regardless of the
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24/67 numerology used in the UE.
[0117] As another example, a common PDCCH can indicate a partition type using the numerology of a UE. In this case, the UE may not need to re-estimate a partition type and partition size. In this case, the common PDCCH may need to be transmitted separately by the UE according to numerology.
[0118] However, as described above, a network can operate in one direction (for example, DL / UL) in a single numerology used independently. Therefore, it may be advantageous to transmit the partition type indication based on the reference numerology. For example, when a network operates with numerology with 15 kHz and 60 kHz SCS and transmits partition type indication based on 15 kHz SCS, a UE using 60 kHz SCS can interpret a different number of DL portions (for example , DL symbols) and UL portions (for example, UL symbol) of the indication based on symbol level alignment or partition level alignment.
[0119] As a detailed example, FIG. 2 illustrates 1 partition based on 15 kHz SCS and 1 partition based on 60 kHz SCS. That is, the duration of 1 symbol (ie the duration of time) based on the 15 kHz SCS can be the same as the duration of 4 symbols based on the 60 kHz SCS. Assuming that the partition format indication based on 15 kHz SCS indicates a form of partition with [Symbol 0 = DL, Symbol 2 = DL ..., Symbol 13 = UL], a UE that operates on the basis of SCS of 60 kHz can interpret Symbol 0 = DL as 4 consecutive DL symbols, can interpret Symbol 2 = DL as 4 consecutive DL symbols and can interpret Symbol 13 = UL as 4 consecutive UL symbols (for example, symbol level alignment) . According to the partition level alignment, a partition having an indicated shape can be interpreted as being repeated four times.
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25/67 [0120] Such a 15 kHz and 60 kHz SCS is exemplary and the same method can be applied to several SCSs that were mentioned above with reference to Table 1 above. For example, when SCS 1 is A kHz, SCS 2 is B kHz and a ratio of B = A * M is satisfied (where A, B and M are a natural number), 1 OFDM symbol length based on SCS 1 can be the same as the M lengths of the OFDM symbols based on SCS 2.
[0121] A common group PDCCH can indicate a partition format based on reference numerology, regardless of the actual numerology used in a UE.
[0122] The reference numerology can be indicated by a network (for example, RRC signaling) or pre-configured. For example, the minimum SCS among several SCSs configured for UEs over the network can be used as the reference numerology.
4. UE Operation Related to Periodic Resource Configuration [0123] In general, NR can be directed to avoid permanent signal or periodic transmissions, some periodic configurations may be necessary for some operations. For example, a synchronization signal block (SS), a PRACH configuration, a CSI-RS configuration, an RRM-RS configuration and / or concession-free resources can be configured periodically.
[0124] In terms of UE performance, it may be desirable to ensure semi-statically configured resources. However, in terms of flexibility, the dynamic exchange of resources between DL / UL / Reserved may be limited. In consideration of these advantages and disadvantages, the following two approaches can be considered.
(i) For example, when a semi-static configuration is provided, a UE can assume that resources are used according to a configuration
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Corresponding 26/67. For example, a common group PDCCH can be set to not change a resource type configured by a semi-static configuration. This method can be advantageous for improving the performance of the UE and simplifying a fallback operation.
(ii) As another example, a resource indicated by a semi-static configuration can be considered as a potential candidate for a semi-static resource. When a common group PDCCH is not activated, a potential candidate can be considered insured. When the group common PDCCH is enabled, the semi-static feature can be used only when being checked by the group common PDCCH. According to this method, it can be advantageous to improve the flexibility of the network. However, even if a partition type does not change in a semi-statically configured fallback configuration, it may be necessary to transmit the common group PDCCH and thus signaling overhead can be increased.
[0125] In consideration of the advantage / disadvantage of (i) and (ii), the semi-static feature can distinguish between a first group and a second group, the first group can perform the operation (i) and the second group can perform the operation (ii). The minimum performance of the UE in the measurement and the minimum opportunities for a PRACH can be ensured through the first group and the second group can be used on demand.
[0126] A common PDCCH can replace at least part of a semi-statically configured resource. Semi-static configurations with a different priority than the common PDCCH, for example, a guaranteed resource and a flexible resource can be considered.
Partition Format Indicator (SFI) for Different Numerology>
[0127] As described above, a partition format indicated by a common group PDCCH can include downlink (D), unknown (X) symbols
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27/67 and / or uplink (U).
[0128] A plurality of partition formats can configure various combinations and a partition format combination can be configured for a UE through upper layer signaling or the like.
[0129] A plurality of numerologies can be configured for a UE. A common group PDCCH SFI can indicate an index of a configured partition format table (or partition format combinations / sets) or UE. When a plurality of BWPs and a plurality of numerologies are configured for 1 UE, there may be a method for indicating partition formats for the respective numerologies. For example, numerologies can be configured separately for the respective BWPs and, in this case, partition formats can be specified for the respective BWPs.
1. UE Partition Format Table for MultiNumerology (1) Single Column Table [0130] A partition format table configured for a UE can be a set of partition formats from a plurality of numerologies.
[0131] For example, when the SCS configured for a UE is 15 and 30 kHz and the partition format table configured for the UE includes 16 of total entries, entries 1 through 8 may correspond to SCS formats of 15 kHz and inputs # 9 to # 16 can correspond to 30 kHz SCS partition formats. A SFI from a common group PDCCH can indicate a partition format index appropriate for the numerology used by the UE.
[0132] When a plurality of BWPs are activated in an UE and the respective BWPs have different numerologies, partition formats of the plurality of BWPs can be indicated through an SFI. For example, the index deviation between partition formats to be applied to numerologies can be used to indicate partition formats for a plurality of BWPs through 1 SFI.
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28/67 [0133] As in the example above, it can be assumed that when the SCS configured for a UE is 15 and 30 kHz and the partition format table configured for the UE includes 16 of the total entries, the entries from # 1 to # 8 correspond to the 15 kHz SCS partition formats and entries # 9 to # 16 correspond to the 30 kHz SCS partition formats. In this case, when an SFI indicates an index from # 1 to # 8, an UE can acquire an unchanged partition format using an SFI index in a 15 kHz SCS BWP, but can interpret an SFI + 8 index in a 30 kHz SCS BWP (that is, index offset 8 is applied) to acquire a partition format from a 30 kHz SCS BWP.
(2) Multiple Column Table [0134] A parent table that is a reference to a partition format table configured for a UE or a partition format table configured for the UE can correspond to a set of partition formats for a plurality of numerologies.
[0135] For example, as shown in Table 4, columns can be defined for the respective numerologies and columns can define partition formats appropriate for the corresponding numerologies.
[Table 4 [] _______________________________________________________________________________________________________________________________________________SCS15 kHz SCS30 kHz SCS60 kHz SCS120 kHzPartition format 1Partition format 2 Partition format N
[0136] When a plurality of BWPs are activated in an UE and the respective BWPs have different numerologies, even if an SFI is indicated, an UE can recognize partition formats of the respective numerologies in one
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29/67 line corresponding to the SFI.
2. Automatic Partition Format Expansion / Reduction [0137] As another example of the present invention, a numerology UE partition format table (for example, reference numerology) can be defined and a rule can be defined to expand or reduce the numerology table. In this case, it may not be necessary for numerology to separately indicate a partition format across a network and thus signaling overhead can be advantageously reduced.
(1) Expansion Rule [0138] When an UE uses SCS greater than reference SCS as a reference in the UE partition format table, the number of partitions based on UE SCS can be increased compared to the number of partitions based on reference SCS included in the same time period. For example, 4 partitions based on 15 kHz reference SCS can have the same duration as 8 partitions based on 30 kHz SCS. Therefore, the UE needs to expand a partition format indicated based on the reference SCS according to the SCS used by the UE. Here, expanding a partition format refers to expanding the number of symbols included in a partition, but it does not refer to expanding the absolute length of time. For example, when the network indicates the 0.5 ms time direction including 14 symbols, the UE can be interpreted as being expanded to include 28/56 / ... symbols in the same 0.5 ms time duration.
[0139] - Option 1: The downlink (D), unknown (X) and uplink (U) directions of symbols of the respective partition formats indicated by the reference SCS can be maintained for the duration of time occupied by the partition format corresponding. For example, it can be assumed that the reference SCS is 15 kHz and a partition format indicated by the reference SCS includes 4
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30/67 D symbols, 6 X symbols and 4 U and SCS symbols used by the UE is 30 kHz. In this case, the 4 D symbols, 6 X symbols and 4 U symbols, included in the indicated partition format, can be expanded to 8 D symbols, 12 X symbols and 8 U symbols, respectively, in relation to an operating UE based on 30 kHz SCS. That is, the time duration of 4 D symbols based on SCS of 15 kHz is the same as the time duration of 8 D symbols based on SCS of 30 kHz and, thus, the UE can interpret 4 D symbols indicated with based on 15 kHz SCS 8 D symbols based on 30 kHz SCS. In this case, the number of D symbols can be expanded, but the sum of the time durations of the D symbols in a partition can be maintained. The UE can interpret X symbols and U symbols in the same way.
[0140] - Option 2-1: When a UE expands each D symbol and each U symbol, different rules can be applied according to the presence of an X symbol before and after a corresponding symbol. For example, when a D symbol, one whose rear portion is an X symbol, is expanded as the case where SCS used by the UE is equal to or greater than twice the reference SCS, the UE can configure 1/2 of a portion back of the expanded D symbol as X. When a U symbol, one whose front portion is an X symbol, is expanded, the UE can configure 1/2 of a front portion of the expanded U symbol as X. For example, when the SCS of reference is 15 kHz and the number of D symbols, X symbols and U symbols is 4, 6 and 4, respectively, the 4 D symbols can be expanded to 4 D symbols + 4 X symbols based on 30 kHz SCS. 6 indicated X symbols can be expanded to 12 X symbols. 4 indicated U symbols can be expanded to 4 X symbols + 4 U symbols based on 30 kHz SCS. As a result, a partition format can be interpreted as 4 D symbols + 20 X symbols + 4 U symbols. Therefore, the length of time corresponding to an X symbol can be further increased compared to the
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31/67 partition indicated.
[0141] - Option 2-2: When the SCS used by a UE is equal to or greater than 4 times the reference SCS and a D symbol, one whose back portion is an X symbol, is expanded, a UE can configure 1 / 4 of a rear portion of the expanded D symbol as an X symbol. When a U symbol, whose front portion is an X symbol, is expanded, 1/4 of a front portion of the expanded U symbol can be configured as an X symbol.
[0142] - Option 2-3: When the SCS used by a UE is equal to or greater than 8 times the reference SCS symbol and a D symbol, the rear portion of which is an X symbol, is expanded, a UE can configure 1 / 8 of a rear portion of the expanded D symbol as an X symbol. When a U symbol, the front portion of which is an X symbol, is expanded, 1/8 of a front portion of the expanded U symbol can be configured as an X symbol.
[0143] - Option 2-4: When the SCS used by a UE is equal to or greater than 16 times the reference SCS symbol and a D symbol, the rear portion of which is an X symbol, is expanded, a UE can configure 1 / 16 of a rear portion of the expanded D symbol as an X symbol. When a U symbol, whose front portion is an X symbol, is expanded, 1/16 of a front portion of the expanded U symbol can be configured as an X symbol.
[0144] - Option 3-1: When the SCS used by a UE is equal to or greater than twice the reference SCS and an X symbol is expanded, an expanded X symbol format can also be differently determined if the D / U are present before and after the symbol X. For example, when a symbol X, whose front portion is a symbol D, is expanded, the UE can configure 1/2 of a front portion of the expanded symbol X as a symbol D. In addition, when an X symbol, the rear portion of which is a U symbol, is expanded, the UE may configure 1/2 of a rear portion of the expanded X symbol as a U symbol.
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32/67 [0145] - Option 3-2: When the SCS used by an UE is equal to or greater than 4 times the reference SCS and an X symbol is expanded, an expanded X symbol format can also be determined differently if the D / U symbols are present before and after the X symbol. For example, when an X symbol, whose front portion is a D symbol, is expanded, the UE can configure 1/4 of a front portion of the expanded X symbol as a U symbol. In addition, when an X symbol, the rear portion of which is a U symbol, is expanded, the UE can configure 1/4 of a rear portion of the expanded X symbol as a U symbol.
[0146] - Option 3-3: When the SCS used by a UE is equal to or greater than 8 times the reference SCS and an X symbol is expanded, an expanded X symbol format can also be determined differently according to whether the D / U symbols are present before and after the X symbol. For example, when an X symbol, whose front portion is a D symbol, is expanded, the UE can configure 1/8 of a front portion of the expanded X symbol as an U symbol. In addition, when an X symbol, the rear portion of which is a U symbol, is expanded, the UE can configure 1/8 of a rear portion of the expanded X symbol as a U symbol.
[0147] - Option 3-4: When the SCS used by a UE is equal to or greater than 16 times the reference SCS and an X symbol is expanded, an expanded X symbol format can also be determined differently according to the symbols D / U present before and after the X symbol. For example, when an X symbol, whose front portion is a D symbol, is expanded, the UE can configure 1/16 of a front portion of the expanded X symbol as a U symbol In addition, when an X symbol, the rear portion of which is a U symbol, is expanded, the UE can configure 1/16 of a rear portion of the expanded X symbol as a U symbol.
(2) Reduction Rule
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33/67 [0148] When a UE uses SCS less than reference SCS, a smaller number of partitions / symbols than the number indicated based on the reference SCS can be present for the same duration. For example, 8 partitions based on 30 kHz reference SCS can have the same length of time as 4 partitions based on 15 kHz SCS. Therefore, the UE needs to expand a partition format indicated based on the reference SCS according to the SCS used by the UE.
[0149] - Option 1-1: When SCS (hereinafter, UE SCS) used by a UE is less than the reference SCS and even a D or U is present in a set of symbols of the reference SCS to be reduced to 1 EU SCS symbol, the corresponding symbol set can be interpreted as a D symbol or U symbol based on the EU SCS.
[0150] - Option 1 -2: When the EU SCS is small and is equal to or less than 1/2 times the reference SCS and a portion of D or U in a set of symbols of the reference SCS to be reduced to 1 EU SCS symbol is equal to or greater than 1/2, the corresponding symbol set can be configured to be a EU SCS D or U symbol. When the D or U portion is less than 1/2, the corresponding set of symbols can be configured to be an X symbol of the EU SCS. For example, when a DDDXXXXXXXXUUU partition format based on the 30 kHz reference SCS is indicated, 2 symbols such as | DD | DX | XX | XX | XX | XU | UU | can be grouped together to define 1 15 kHz EU SCS symbol. | DX | can be converted to D and | XU | can be converted to U. A DDDXXXXXXXXUUU partition format based on 30 kHz SCS can be converted to a DDXXXUU partition format based on 15 kHz UE SCS.
[0151] - Option 1 -3: When the EU SCS is small and is equal to or less than 1/4 times the reference SCS and a portion of D or U in a set of symbols
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34/67 of the reference SCS to be reduced to 1 EU SCS symbol is equal to or greater than 3/4, the corresponding symbol set can be configured to be a D or U symbol of the EU SCS. When the D or U portion is less than 3/4, the corresponding symbol set can be configured to be an X symbol of the EU SCS.
[0152] - Option 1 -4: When the EU SCS is small and is equal to or less than 1/8 times the reference SCS and a portion of D or U in a set of symbols of the reference SCS to be reduced to 1 EU SCS symbol is 7/8 or more, the corresponding symbol set can be configured to be a EU SCS D or U symbol. When the D or U portion is less than 7/8, the corresponding symbol set can be configured to be an X symbol of the EU SCS.
[0153] - Option 1 -5: When the EU SCS is small and is equal to or less than 1/16 times the reference SCS and a portion of D or U in a set of symbols of the reference SCS to be reduced to 1 EU SCS symbol is equal to or greater than 15/16, the corresponding symbol set can be configured to be a EU SCS D or U symbol. When the D or U portion is less than 15/16, the corresponding symbol set can be configured to be an X symbol of the EU SCS.
[0154] - Option 2-1: When the SCS of UE is less than the reference SCS and even an X is present in a set of symbols of the reference SCS to be reduced to 1 symbol of the EU SCS, the set of corresponding symbols can be converted into an X symbol of the EU SCS.
[0155] - Option 2-2: When the EU SCS is small and less than or equal to 1/2 times the reference SCS, a set of reference SCS symbols to be reduced to 1 EU SCS symbol includes D and X or X and U, and a portion of X in the symbol set is equal to or greater than 1/2, the symbol set
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The corresponding 35/67 can be configured to be an X symbol of the EU SCS. When the X portion in the symbol set is less than 1/2, the corresponding symbol set can be configured to be a D or U symbol of the EU SCS.
[0156] - Option 2-3: When the EU SCS is small and less than or equal to 1/4 times the reference SCS, a set of reference SCS symbols to be reduced to 1 EU SCS symbol includes D and X or X and U, and a portion of X in the symbol set is equal to or greater than 3/4, the corresponding symbol set can be configured to be an EU SCS X symbol. When the X portion in the symbol set is less than 3/4, the corresponding symbol set can be configured to be a D or U symbol of the EU SCS.
[0157] - Option 2-4: When the EU SCS is small and is equal to or less than 1/8 times the reference SCS, a set of reference SCS symbols to be reduced to 1 EU SCS symbol includes D and X or X and U, and a portion of X in the symbol set is equal to or greater than 7/8, the corresponding symbol set can be configured to be an X symbol of the EU SCS. When the X portion in the symbol set is less than 7/8, the corresponding symbol set can be configured to be a D or U symbol of the EU SCS.
[0158] - Option 2-5: When the EU SCS is small and less than or equal to 1/16 times the reference SCS, a set of reference SCS symbols to be reduced to 1 EU SCS symbol includes D and X or X and U, and a portion of X in the symbol set is equal to or greater than 15/16, the corresponding symbol set can be configured to be an X symbol of the EU SCS. When the X portion of the symbol set is less than 15/16, the corresponding symbol set can be configured to be a SCS D or U symbol
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36/67 EU.
[0159] - Option 3: When the EU SCS is less than the reference SCS and a set of symbols from the reference SCS to be reduced to 1 SCS symbol includes all D, X and U, the corresponding set of symbols can be configured to be an X symbol of the EU SCS.
[0160] - Option 4-1: When the EU SCS is less than the reference SCS and D and U are mixed in a set of symbols of the reference SCS to be reduced to 1 SCS symbol, the corresponding set of symbols can be configured as an X symbol of the EU SCS.
[0161] - Option 4-2: When the SCS of UE is less than the reference SCS and D and U are mixed in a set of symbols of the reference SCS to be reduced to 1 SCS symbol, the UE can recognize the set of corresponding symbols as an error and can disregard a partition format of a partition included in the corresponding symbol set.
(3) Reference Numerology Standard [0162] There may be several methods for notifying a UE about reference numerology to configure reference numerology over a network.
[0163] - Option 1: for example, when notifying a UE about a partition format table (for example, combinations of partition formats), the network can also notify the UE about the reference numerology referred to by the format format table partition.
[0164] However, when standard reference numerology is defined and a partition format table based on standard reference numerology is used, the network may not separately notify the UE about reference numerology.
[0165] Standard reference numerology can be defined, for example, as follows, but is not limited to this. (I) The lowest numerology among
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37/67 configurable numerologies for a UE can be selected as standard reference numerology. For example, assuming that the SCS of configurable numerology for the UE is 15, 30, 60 and 120 kHz, the network can define 15 kHz as the standard reference numerology. (II) The largest numerology among configurable numerologies for a UE can be selected as standard reference numerology. For example, assuming the SCS of configurable numerology for the UE is 15, 30, 60 and 120 kHz, the network can define 120 kHz as standard reference numerology, (ill) As another example, 15 kHz can be fixed in numerology standard reference.
[0166] - Option 2: As another example, the network can define numerology for a control channel used to indicate an index in a partition format table configured for the UE as reference numerology.
[0167] - Option 3: As another example, numerology of a band in which a corresponding partition format is actually used can be defined as reference numerology.
3. Inherit previous SFI [0168] The method for converting a partition format depending on a UE's SCS by the UE when a partition format is transmitted based on the reference SCS (or reference numerology) has been described above.
[0169] When a carrier is changed after the UE applies a specific SFI and the numerology of the changed BWP / carrier is different from the previous BWP / carrier, if the specific SFI is reapplied by the UE it can be issued according to the conversion rule of partition format mentioned above.
[0170] - Option 1: For example, when the changed BWP / carrier numerology is different from a previous BWP / carrier, the UE can disregard a pre-indicated partition format and can perform a fallback operation to a next SFI of a time point at which the BWP / carrier is changed.
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38/67 [0171] - Option 2: As another example, when the modified BWP / carrier numerology is different from a previous BWP / carrier, the UE can apply a partition format that is modified according to the changed numerology up to a next SFI to a time point at which the BWP / carrier is changed. However, in the case of a format that is not supported by the modified partition format, the UE may disregard the corresponding partition format and may perform a fallback operation.
4. Inherit previous SFI in Beam Switching [0172] A plurality of beams can be configured for a UE and, as necessary, beam switching can occur. As such, when a beam is switched, the UE may need to select whether an existing applied SFI is applied to a new beam without change.
[0173] - Option 1: The UE can disregard an existing partition format up to a next SFI from a point in time when beam switching occurs and can perform a fallback operation.
[0174] - Option 2: The UE can comply with an existing partition format up to a next SFI from a pent period in which the beam switching occurs. When the switch's numerology is different from a previous beam, the UE can apply a partition format modified according to the changed numerology. However, in the case of a format that is not supported by the modified partition format, the UE may disregard the corresponding partition format and may perform a fallback operation.
5. Defining the Reference Numerology [0175] To perform a method to modify a partition format according to numerology, as described above, it may be important to define the reference numerology. When the programming numbers / programmed carriers are the same in cross carrier programming, it may not be
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39/67 there are problems in applying the partition format modification rule mentioned earlier. However, a plurality of BWPs can be configured for the respective carriers and the numerologies may be different for the respective BWPs.
[0176] When an SFI is defined / signaled for each cell (ie, carrier) in a common group PDCCH transmitted via a P Cell, it may be necessary to define the reference numerology of an SFI for each cell.
[0177] For example, in the case of Cell P, the numerology to transmit the group common PDCCH can correspond to the reference numerology.
[0178] In the case of an S Cell, the following options can be considered.
[0179] - Option 1: A partition format can be indicated based on the numerology of a currently activated BWP.
[0180] - Option 2: The numerology of a first BWP activated in the S Cell can be defined as reference cell of the S Cell.
[0181] - Option 3: The numerology of a standard S Cell BWP can be defined as S Cell reference numerology.
Partition Format for Multiband>
[0182] The partition format indication can be used mainly in a TDD environment, but it can be used to indicate a partition format in an FDD band. Each FDD band can usually be fixed to D or U, but a network can allow each FDD band to be used for another use through 'Unknown'. In this case, the network needs to indicate a D-Band and U-Band partition format in an FDD and therefore there is a need for a method for this purpose.
[0183] In an LTE-NR coexistence environment, a network can allocate a supplemental uplink (SOUTH) that temporarily uses an LTE UL band for a
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40/67 NR user for an additional UL band from an NR user. In this case, when the NR user operates on a TDD, the network must simultaneously indicate a partition format of an NR TDD band and a partition format of SOUTH.
[0184] One such method for simultaneously indicating a partition format for two or more bands is described below.
1. Single Column Table [0185] For example, a table in which the partition formats of two or more bands (for example, BWPs) are deployed contiguously in one row can be defined / configured.
[0186] FIG. 3 illustrates combinations of partition formats according to an embodiment of the present invention.
[0187] For example, when a Bandal partition format is represented as SF1 and a Band2 partition format is represented as SF2, a partition format group transmitted to a UE over a network may be in the form of SF1 + SF2 + ....... The partition format group can be an entry in the partition format table and these entries can be grouped together to configure the partition format table.
[0188] The network can configure partition format combinations corresponding to the partition format table for the UE via upper layer signaling and then notify the UE of a partition format combination for a specific entry via a common PDCCH group.
[0189] Furthermore, SCS can be different for each band, even in an input. Thus, the number of partitions of the respective SFs can also be different.
[0190] The partition format table can be configured in such a way that partitions corresponding to the same specific time duration are implemented contiguously between the partition formats of the respective
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41/67 bands and then the partitions corresponding to the same duration of next time are implemented in a contiguous manner. For example, it can be assumed that Band 1 numerology is 60 kHz SCS and Band 2 numerology is 15 kHz SCS. Band 1 can have 4 partitions and band 2 can have 1 partition for 1 ms. When the length of time for a partition format to be notified to a UE over a network is 2 ms, the number of partitions for Bandal is 8 for 2 ms and the number of partitions for Band2 is 2 for 2 ms. In this case, the network can implement 2-band partition formats in the form of 1 partition of 4 partitions of Bandal + 1 partition of Band2 + 4 partitions of Bandal + 1 partition of Band2.
[0191] For example, the network can deploy 1 partition of 4 partitions + 1 partition of Banda2, which corresponds to the same duration of 1 ms, and then it can deploy 4 partitions of Bandal + 1 partition of Banda2, which corresponds to next time duration of 1 ms.
[0192] Such partition format deployment can be performed regardless of the number of bands.
[0193] FIG. 4 illustrates combinations of time partition formats according to another embodiment of the present invention. For convenience, it can be assumed that the number of bands is 2 or 3 in FIG. 4. For example, in the case of input 2, Band 1, Band 2 and Band 3 have the same SCS. In the case of input 4, it can be assumed that SCS Band 2 is twice SCS Band 1 and SCS Band 1 is twice SCS Band 3.
[0194] The method of FIG. 3 or 4 can be used when a network indicates partitions corresponding to the same length of time in relation to a plurality of bands at once.
2. MultiColumn Table [0195] Figs. 5 and 6 illustrate combinations of time partition formats according to another embodiment of the present invention.
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42 / U7 [0196] The partition formats of a plurality of bands can be arranged contiguously in a column, as illustrated in FIG. 3 or 4 but, according to another embodiment of the present invention, a column can be defined for each band and a partition format can be indicated.
[0197] 3. Multi-Bands Supporting Multinumerology [0198] The method for indicating a form of partition of all the numerologies to be supported by a band through a partition format table has been described above in relation to modalities related to the Table 4 above. The method of indicating time partition formats for a plurality of bands through a time partition format table has been described in relation to modalities related to FIGs. 3 to 6.
[0199] The above modalities can also be combined to consider a method for simultaneously indicating partition formats of all numerologies to be supported for each of the plurality of bands. For example, a modality can be formed by combining the modalities related to Table 4 above and the modalities related to FIGs. 3 a
6.
[0200] For example, a column can be defined for each band and a sub-column can be defined for numerologies of the respective bands and thus a network can indicate partition formats for respective numerologies of a plurality of bands in one row at a time .
[0201] FIG. 7 illustrates a partition format combination according to an embodiment of the present invention.
[0202] In FIG. 7, the number of bands and the number of numerologies of the respective bands can be changed as an example. As the number of bands and / or the number of numerologies of the respective bands is increased, a size of the time partition format table illustrated
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43/67 can also be increased.
4. Reference Numerology Configuration [0203] When partition formats for a plurality of bands are indicated using a table, the numerology of each band needs to be considered. This is because a method for indicating partition formats of the respective bands is changed according to the determined reference numerology. Each band can be any of, for example, a DL band, an UL band, a SOUTH band and a TDD band, but is not limited to them.
The methods considered are described below.
[0204] - Option 1: A partition format indicated by a partition format table can be a partition format according to the numerology of each band. For example, when Bandal is 30 kHz SCS and Band2 is 15 kHz SCS, a partition format for each band can be defined as a partition format for 30 kHz SCS and a partition format for 15 kHz SCS. When partition formats for 30 kHz SCS / 15 kHz SCS are entered in a table, a combination of 30 kHz SCS / 15 kHz SCE partition format or a partition format column for each band can be deployed.
[0205] - Option 2: A partition format can be indicated based on the lowest numerology among numerologies of a plurality of bands. A UE can modify a specified partition format according to the numerology of each band, using the aforementioned partition format expansion method.
[0206] - Option 3: A partition format can be indicated based on the larger numerology between numerologies configured for a plurality of bands.
[0207] - Option 4-1: Reference numerology can be defined
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44/67 separately and a partition format for each band can be indicated based on the reference numerology.
[0208] - Option 4-2: The reference numerology can be defined separately and partition formats of only a few bands can be indicated based on the reference numerology. A partition format according to the numerology of a corresponding band can be indicated for the other band (s). For example, some bands to which reference numerology is applied can be at least one from a DL band, a UL band, a SOUTH band and a TDD band.
[0209] The reference numerology in options 4-1 and 4-2 can be determined using the method mentioned above to determine the reference numerology.
[0210] Although the proposed methods can be implemented independently, some proposed methods can be combined (or integrated). It can be regulated that the information indicating whether the proposed methods are applied or not (or information about the rules of the proposed methods) transmitted to a UE in a predefined signal (for example, a physical layer signal or an upper layer signal) a base station.
<Common Group PDCCH »[0211] The content and expected size of the DCI payload transmitted through a common group PDCCH are described below.
[0212] A method for signaling the group common PDCCH is now described. An example of the method for signaling may include a method for allocating and transmitting a reserved resource and a method for configuring and transmitting a search space.
[0213] When information about a partition type is transmitted via the common group PDCCH, if a method for transmitting a partition type
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45/67 for an UE that operates with a plurality of CCs is effective or is not described below.
1. Content of Group Common PDCCH [0214] (1) Partition Format Indication [0215] The group common PDCCH can be used to notify a UE about a partition format. The partition format can be indicated in several types. A payload size of the common group PDCCH can be varied according to the type of partition format indicated.
[0216] A size of 1 partition (for example, length in time domain) can be changed according to numerology. The number of partitions configuring 1 partition can be changed according to numerology.
(i) Partition Type [0217] The common group PDCCH can indicate a type of at least one partition.
[0218] For example, a space can be classified as shown in Table 5 below, but is not limited to it.
[Table 5]
Partition description just D Partition in which only downlink is supported only U Partition on which only uplink is supported D-centric Partition where downlink is supported on most of the symbols that configure the partition U- centric Partition on which uplink is supported on most of the symbols that configure the partition Data region (DR) Partition used for other data but no specific UE data as in MBSFN subframe Reserved Partition occupied by a network as needed but no specific use of UE
[0219] In the case of D-centric and U-centric partition types, only if a corresponding partition is D-centric or U-centric can be indicated and therefore a configuration (for example, downlink and uplink) of a symbol real included in
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46/67 corresponding partition needs to be predefined. A DL / UL portion on a D / U-centric partition can be predefined or can be configured over a network. One or more D / U-centric standards may be present according to a DL / UL resource configuration.
[0220] The use of the reserved / DR partition can be predefined or not. For example, the use of the reserved / DR partition can be predefined through system information, top layer indication or the like. When the use of a reserved / DR partition is not defined, a network can notify a UE about the use while indicating a partition type via the common group PDCCH or may not indicate the use if it is not necessary for the UE to know the use of the reserved / DR partition. The reserved resource can be configured separately from a partition type. For example, the network can configure a reserved resource via dynamic / semi-static signaling.
(ii) Partition Type Pattern [0221] A common group PDCCH can indicate a type of plurality of partitions. For example, the common group PDCCH can indicate at least one of the combinations of a plurality of partitions. When a network indicates the respective types of a plurality of partitions one by one, it can be ineffective that a payload size of the common group PDCCH is increased and the signaling overhead is increased. Therefore, the number of partitions to indicate and each type of partition can be defined as a standard and the network can notify the UE about an index of the standard via the common group PDCCH.
[0222] A plurality of partition type patterns can be defined. For example, the partition type pattern can be defined as [eriodicity / partition types or patterns or a set of partition types] but is not limited to these.
[0223] FIG. 8 illustrates patterns of partition formats according to a
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47/67 embodiment of the present invention. In FIG. 8, DU refers to a symbol, half of which are D symbols and the other half of which are U symbols.
[0224] In the case of an FDD system, a partition corresponding to D in FIG. 8 can correspond to a partition format of a DL band (for example, DL BWP) and a partition corresponding to U in FIG. 8 can be interpreted as a partition format of a UL band (for example, UL BWP). For example, a configuration of a pattern obtained by combining a partition format D and a partition format U for a UE by a base station can be interpreted as a configuration of a pattern obtained by combining a partition format of a DL band ( for example, DL BWP) and a UL band partition format (for example, UL BWP) for the UE by the base station.
[0225] A plurality of partition type patterns to be used in a corresponding cell or a corresponding group can be defined / configured and a network can notify a UE about patterns to be used among a plurality of partition type patterns. For example, a subset can be flagged for the UE between defined standards. FIG. 8 illustrates 12 total patterns and, in this case, information indicating that patterns # 5 to # 8 defined using sections of 2 partitions between 12 patterns are available can be flagged for the UE. In this case, 4 patterns from # 5 to # 8 can be re-indexed and can be considered as patterns from # 1 to # 4.
[0226] As such, when a subset of partition type patterns is pre-notified to the UE, the network can sequentially transmit only the indexes of the re-indexed patterns to the common group PDCCH. Consequently, the signaling overhead of the group common PDCCH can be reduced. For example, the group common PDCCH may not inevitably cover all 12 patterns and can be configured to cover 4 patterns, in which case a payload size of the group common PDCCH can be reduced.
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48/67 [0227] Information about the subset of partition type standards can be transmitted to the UE via a MAC control element (CE) or can be transmitted via the common group PDCCH. Alternatively, the network can predefine a period in which a pattern must be indicated using the system information. Alternatively, information about a subset of partition type patterns can be transmitted via UE-specific upper layer signaling.
[0228] A long period pattern can be defined in the way that short period patterns are repeated. In this case, in a situation where the network needs to simultaneously indicate two partition formats, the pattern information in the long period can be advantageously replaced by the pattern information in the short period.
(ill) Symbol Unit Indication [0229] According to another embodiment of the present invention, a common group PDCCH can indicate a type of partition in symbol units by configuring a partition. For example, a resource type such as D / U / Reserved in Table 6 below can be applied in units of symbols.
[0230] Table 6 below shows an exemplary partition format assuming that 1 partition includes 7 symbols.
[Table 6]
Partition Format Symbol 0 Symbol1 Symbol 2 Symbol3 Symbol 4 Symbol5 Symbol6 1 D D D D U U U 2 D D R R R R U 3 D U U U U U U 4 D D DR DR DR DR DR
(iv) Symbol Pattern [0231] Although the method for indicating an index of a partition pattern by a common group PDCCH has been described above, the common PDCCH dE
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49/67 group may indicate an index of a pattern of symbols according to another embodiment of the present invention.
[0232] Table 7 below shows an exemplary symbol pattern (or partition format) under the assumption that 1 partition includes 7 symbols.
[Table 7]
Partition Format Symbol 0 Symbol 1 Symbol 2 Symbol3 Symbol 4 Symbol5 Symbol6 1 D D D R R U U 2 D DR DR DR U U U 3 R R R R R U U
(2) Other Information [0233] The common group PDCCH can include still other information in addition to the partition format information.
(I) Drill indication: The common group PDCCH may include drilling information for URLLC. A period used as a URLLC can be indicated in units of partitions or in units of symbols.
(ii) Information on semi-static resources: The common group PDCCH can include information on a semi-static resource, such as CSI-RS. For example, the common group PDCCH can indicate information about what a corresponding semi-static resource is or information about a period, duration of transmission time and the like, when the corresponding semi-static resource has the period.
2. Transmission of Group Common PDCCH [0234] As a method for transmission of a group common PDCCH over a network, a method for configuring and transmitting a search space for the group common PDCCH and a method for securing and transmitting a resource reserved for the common group PDCCH can be considered.
(1) Transmission of Common Group PDCCH Using Reserved Resource [0235] A network can pre-secure a resource (for example, RE, REG, RB
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50/67 and CCE) in which a common group PDCCH is to be transmitted.
[0236] The common group PDCCH can also be a control channel and therefore can be deployed in a CORESET. In addition, it may be desirable to deploy a resource position reserved for the common group PDCCH to minimize blocking with other control channels. In particular, the common group PDCCH can avoid blocking with a CSS to a maximum extent.
[0237] When a position in a logical domain, in which a control channel is transmitted, is defined, a logical position of the resource reserved for the common group PDCCH can be immediately before or behind the CSS. Alternatively, the resource reserved for the common group PDCCH can be positioned in the last portion of a CORESET or it can be positioned to be separated from an initial index or final CSS index by a predetermined deviation. In this case, the deviation can be different for each cell / group. The deviation can be notified to a UE through system information, upper layer signaling or the like.
[0238] Alternatively, the resource for the common group PDCCH can be deployed in the CSS. In this case, a common group PDCCH size can be equal to or less than the size of a smaller candidate among control channel candidates in CSS. In this case, the resource reserved for the group common PDCCH can be included in the CSS candidate and, in this respect, the UE can basically perform blind detection (DB) in the CSS, regardless of whether the group common PDCCH is detected in the reserved resource in the CSS.
[0239] A resource position reserved for the common group PDCCH can be notified to the UE via system information, upper layer signaling, or the like. When the common group PDCCH is transmitted through a candidate in the CSS, the number of available candidates can be reduced to transmit PDCCH (for example, common control information, but not a
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51/67
Common group PDCCH) in CSS, which causes a similar result to blocking CSS. Thus, when the group common PDCCH is configured in a CSS, the UE can assume that a candidate, to which the group common PDCCH is mapped, is not used as a CSS candidate from another channel and can assume that the candidate is an invalid candidate. The UE can ignore blind detection on the invalid candidate and can proceed to the next candidate. In addition, the group common PDCCH can be set to be transmitted using a CSS as a general PDCCH, and in this case, a general blind detection procedure in the CSS can also be performed on the group common PDCCH in the same way.
[0240] FIG. 9 illustrates the reserved allocation of resources for a common group PDCCH according to an embodiment of the present invention. The common group PDCCH can be mapped to a block indicated by dotted lines in FIG. 9.
[0241] (a) of FIG. 9 illustrates the case where a resource reserved for the common group PDCCH is allocated to a first candidate. Consequently, a UE can omit blind detection of a general PDCCH in relation to the corresponding block.
[0242] (b) of FIG. 9 illustrates the case where a resource reserved for the common group PDCCH is allocated to a next portion of the last candidate.
[0243] (c) of FIG. 9 illustrates the case where a resource reserved for the common group PDCCH is allocated to a position with a predetermined deviation from the last candidate.
(2) Transmission of Common Group PDCCH through Search Space [0244] A network can configure a search space in which a common group PDCCH must be transmitted and a UE can perform blind detection in a corresponding search space to detect a common group PDCCH.
(i) With the G-RNTI
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52/67 [0245] A search space in which a common group PDCCH is to be transmitted is referred to as a GSS. A temporary radio network identifier (RNTI) required for the detection of the common group PDCCH in the GSS is referred to as a G-RNTI. For example, a common group PDCCH CRC can be shuffled or masked through the G-RNTI.
[0246] 1 UE can have one or more G-RNTIs. For example, a UE can be configured with one or more GSSs. The GSS can be defined regardless of its number.
The. CSS GSS [0247] For example, a network can deploy randomly to a CSS. To deploy GSS in CSS, the size and / or the number of GSS candidates can be equal to or less than the size and / or the number of CSS candidates. GSS candidates can be contiguously deployed or can be distributed and deployed separately.
[0248] When a GSS candidate size is the same as a CSS candidate size, a UE needs to additionally only perform the CRS exam in the GSS (for example, CRC exam via R-RNTI) during the performing blind detection in CSS and thus a problem in terms of additional blind detection overhead due to the additional implementation of GSS can be overcome.
[0249] FIG. 10 illustrates a GSS deployed in a CSS according to an embodiment of the present invention.
[0250] An environment in which the size of a larger candidate among GSS candidates is equal to or less than the size of the smallest candidate in a CSS and the number of candidates for GSS is equal to or less than half the number of CSS candidates can be considered.
B. GSS in CORESET
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53/67 [0251] Similar to a USS, a network can deploy GSSs randomly in a CORESET according to a hashing function using a G-RNTI. Candidates for a GSS can be deployed contiguously or can be deployed and deployed separately.
(ii) Without the G-RNTI
The. CSS GSS [0252] A network can deploy a GSS in a CSS. The present modality is partially similar to the aforementioned method of implementing GSS in CSS, but according to the present modality, the network can form GSS and can implement GSS in CSS to reduce the possibility of blocking with a control channel to be transmitted in the CSS. The size / number of GSSs can be equal to or less than the size / number of CSS candidates.
[0253] When there is no G-RNTI, the position of a candidate for a GSS needs to be determined. When a size of the GSS candidate is the same as the size of a CSS candidate, a UE a UE needs to additionally only perform the CRS exam in the GSS while performing blind detection in the CSS and thus the number of additional blind detections due to the additional deployment of GSS it can be reduced.
[0254] A position for a GSS candidate to be deployed in each CSS candidate can be defined via system information or upper layer signaling. GSS candidates can be implemented contiguously or can be distributed or deployed separately.
[0255] FIG. 11 illustrates GSS candidates with a fixed position in a CSS according to an embodiment of the present invention.
[0256] When a GSS candidate and a CSS candidate are the same size, an initial index of a CCE, corresponding to a candidate of
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54/67 even number or odd number of the CSS, can be used as an initial index of a GCE Candidate CCE.
[0257] When the number of CCEs of the GSS candidate is less than that of the CSS candidate, an index of an even-numbered or odd-numbered CCE in an even-numbered or even-numbered CSS candidate can be used as an initial index of the GCE candidate's CCE.
B. GSS in CORESET [0258] When GSSs are configured contiguously without a separate RNTI as an LTE CSS, an initial index of a GSS can be given by deviating from an initial index or final index of a CSS.
[0259] The deviation can be different for each cell / group. The deviation can be notified to the UE through system information, upper layer signaling or the like.
[0260] When a group common PDCCH is transmitted to a part of a CSS (when a GSS candidate is fixed or not), a UE can assume that the group common PDCCH is transmitted only on a partition in which the CSS is transmitted or mini-partition.
[0261] When the group common PDCCH is transmitted to a CSS and a separate resource, a partition and a partition resource to which the group common PDCCH is to be transmitted or the mini-partition can be configured separately from the CSS.
[0262] When a downlink control information size (DCI) of the common group PDCCH is different from the DCI transmitted in the CSS, a set of partitions to be monitored for the group common PDCCH by a UE may be different from a set CSS monitoring system. More generally, a partition monitored by the UE or a set of minipartition can be configured differently for each RNTI or a partition monitored by the
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UE or a mini-partition set can be configured differently for each DCI size.
3. Partition format indication for multiple component carriers [0263] When a UE uses a plurality of carriers (for example, carrier aggregation), a network can notify the UE about a partition format to be used on each carrier.
(1) Multiple CC group common PDCCH transmission [0264] A network can transmit a group common PDCCH to each CC to transmit the partition format indication to each CC. Alternatively, the network can indicate partition formats for all CCs through a primary CC (PCC).
[0265] When the number of CCs used by the UE is high, the network can group the CCs into a plurality of groups and define a CCP for each group. The network can indicate a CC partition format in a corresponding group through a CCP in each group.
[0266] A method for grouping CCs is described below.
(i) CCs with the same Partition Format [0267] A network can group CCs with the same partition format for the same group. In this case, the network can only indicate a partition format for a CC without indicating a partition format for each CC. Consequently, the amount of information required for indicating the partition format and signaling overhead can be reduced.
(ii) CCs with the same numerology [0268] A network can group CCs with the same numerology for the same group. In this case, all the CCs in a group can have the same partition size. Thus, the network may need to consider a difference in
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56/67 partition indexes due to a numerological difference when indicating partition formats with the same length of time.
[0269] When a network transmits partition format information on a plurality of CCs, a payload size of a common group PDCCH can be significantly increased. A maximum payload size of the common group PDCCH is [artition format information of 1 CC * the number of CCs] and thus it can be difficult to increase a partition format information size of 1 CC. The partition format information in symbol units requires a large amount of information and, therefore, the partition format indication to be used when a plurality of CCs configured for the UE can be indication of partition type or indication of type of partition. partition.
[0270] A payload size of a common group PDCCH for multiple CCs can be determined if the CCs are grouped. When the grouped CCs have the same numerology, there is no problem in the case of the same type of partition indicated, but when the respective CCs need to be assigned different types of partitions, it can be difficult to support a plurality of CCs in one by one item. partition format indication.
[0271] When a partition format is indicated using a partition type pattern, a problem may arise when periods of partition formats to be indicated by CCs in a group are different. As a case in which partition format lengths to be received by referral are different for respective CCs, when a UE receives a long period partition format, the partition format can be converted to a short period partition format . Alternatively, the network can perform the indication of a plurality of partition format periods through a partition format indication item.
[0272] For example, a pattern from a long partition pattern can be
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57/67 defined through a pattern in which a short partition pattern is repeated.
[0273] As another example, a short partition period pattern associated with a long partition period pattern can be predefined. Even if a UE receives a pattern from a long partition pattern, the UE can use a pattern from a short partition period combined with the corresponding pattern.
[0274] A more detailed example is described below with reference to FIGs. 12 and 13. FIGS. 12 and 13 illustrate multiple CC partition patterns according to an embodiment of the present invention.
[0275] In FIGs. 12 and 13, it is assumed that CCs in a group include a CC that is assigned 4 partitions as a partition pattern period and a CC that is assigned 2 partitions as a partition pattern period.
[0276] With reference to FIG. 12, a 4-part period pattern can be defined in the way that the 2-part period patterns are repeated twice.
[0277] With reference to FIG. 13, 2-part period patterns associated with 4-part period patterns can be defined.
[0278] When numerologies are different for the respective CCs, but the CCs have the same length of time for the partition pattern indication, a partition pattern period can be determined according to a difference in numerology. For example, a pattern of a short partition pattern can be used for a CC with a short SCS and a pattern of a long partition pattern defined through the pattern of a short partition pattern can be used for a CC for large SCS. This is because, in the case of the same length of time, the number of partitions of a CC with a large SCS is greater than the number of partitions of a CC with a small SCS.
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58/67 [0279] FIG. 14 illustrates multiple CC partition patterns according to another embodiment of the present invention. It can be assumed that a 4-part pattern is a CC pattern using 30 kHz SCS and a 2-part pattern is a CC pattern using 15 kHz SCS.
[0280] In (a) of FIG. 14, a 4-part period pattern can be defined in the way that the 2-part period patterns are repeated twice.
[0281] In (b) of FIG. 14, a 4-part period pattern and a 2-part period pattern can be associated with each other.
[0282] As such, partition patterns for a plurality of CCs using different numerologies can be indicated through a partition format indication.
[0283] When the partition formats of a plurality of carriers are indicated via a common group PDCCH, a period of a partition format for each carrier can be matched based on a carrier on which the group common PDCCH is transmitted . When a partition format period for each carrier is less than a reference period, a new set of configurations according to repeated patterns / periods can be provided. The case in which a period of a specific operator's partition format is longer than a reference period can be treated in a similar way.
(2) Partition Format Indication Methods [0284] A CC index based on a network and a CC index based on a UE can be different. Thus, a network can consider a different CC index when indicating a partition format for a CC.
[0285] For example, when a CC based on a network is an NCC and a CC based on a UE is a UCC, NCC 1 can be classified into one
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59/67 plurality of UCCs (e.g., UCC 1 to UCC n). When the network specifies a partition format based on the UCC as a reference for the UE, ο the UE can properly recognize the indicated information.
[0286] A relationship between the NCC and the UCC can be transmitted specifically to the UE. For example, when the number of CCs configured as the NCC is m and the number of CCs configured as the UCC is n, a relationship between the NCC and the UCC can be defined by a network. The relationship between the NCC and the UCC can be signaled through a MAC CE, system information or a common group PDCCH.
[0287] Table 8 below shows an example of a relationship between an NCC and a UCC in relation to an UE.
[Table 8]
NCC1 ucci UCC2 IJCC3 NCC2 IJCC4 UCC5 NCC3 UCC6 UCC7 UCC8 UCC9 .....
(i) Partition format indication in terms of the Network [0288] A network can indicate a partition format based on an NCC index. After receiving the indication of a partition format based on an NCC index, an UE can find an index of an UE UCC, corresponding to the NCC, and can use the indicated partition format as a corresponding partition format of the UCC of the HUH.
Petition 870190015766, of 02/15/2019, p. 78/109
60/67 (ii) Partition Format Indication in terms of UE [0289] A network can indicate a partition format based on an index of a UCC. The network can define and indicate a partition format as much as the UCC_max number of UCCs of a UE that has a greater number of UCCs among the UEs belonging to the same group. The UE that has UCCs, whose number is less than UCC_max, can selectively acquire only referral information as much as the number of UE UCCs and can determine a partition format for each UE UCC.
[0290] When mapping between the NCC and the UCC is performed in a similar manner to a plurality of UEs, it can be easy to indicate a partition format based on a UCC index.
[0291] FIG. 15 illustrates a flow of a method for transmitting and receiving downlink control information (DCI) according to an embodiment of the present invention. FIG. 15 illustrates an example of the methods mentioned above and, therefore, a repeated description of the above description may not be given here.
[0292] Referring to FIG. 15, a base station can transmit information about reference SCS between numerologies of a plurality of subcarrier spacing (SCS) (1505). Information about the reference SCS can be transmitted via upper layer signaling.
[0293] The base station can generate DL control information, including information about a partition format (1510). The base station can transmit DL control information to an UE group including an UE through a common EU group physical downlink control (PDCCH) channel. (1515).
[0294] The UE can acquire information on a partition format, from the DL control information (1520). DL control information can indicate a partition format based on the reference SCS. When the SCS of the UE is different from the reference SCS, the UE can convert a partition format of the SCS
Petition 870190015766, of 02/15/2019, p. 79/109
61/67 reference according to the EU SCS.
[0295] The duration of time for 1 partition can be variable depending on the SCS. The reference SCS can be configured to be equal to or less than the UE SCS in such a way that the time duration of 1 partition based on the reference SCS is equal to or greater than the time duration of 1 partition based on the SCS of the UE.
[0296] When the SCS of the UE is M times the reference SCS, the UE can interpret 1 partition based on the reference SCS as M contiguous partitions based on the SCS of the UE.
[0297] The UE can determine, based on information about the partition format, whether each of a plurality of symbols included in the corresponding partition corresponds to downlink (D), uplink (U) or flexible (X). When the SCS of the UE is M times the reference SCS, the UE can interpret a D, U or X symbol based on the reference SCS as number M of D, U or X symbols based on the UE SCS.
[0298] Information about a partition format can indicate at least one of the partition formation combinations configured in the UE.
[0299] A plurality of frequency bands can be configured for the UE and each partition format combination can be obtained by combining a plurality of partition formats for a plurality of frequency bands.
[0300] Each partition format combination can be obtained by combining a partition format for a frequency range of DL and a partition format for a frequency band of UL. Alternatively, each partition format combination can be obtained by combining a partition format for a new radio access technology (NR) frequency band and a partition format for a long-term evolution frequency (LTE) frequency band.
Petition 870190015766, of 02/15/2019, p. 80/109
62/67 [0301] Partition format combinations configured for a UE can be received via upper layer signaling and can be a subset of a plurality of partition format combinations supported in a wireless communication system. For example, a partition format of a UL band (for example, UL BWP) and a partition format of a DL band (for example, DL BWP) can correspond to a combination of partition format. Alternatively, a BWP partition format in an NR band and a BWP partition format (for example, SOUTH) in an LTE band can correspond to a partition format combination. The base station can configure at least one partition format combination between a plurality of partition format combinations via RRC signaling to the UE. Then, the base station can indicate at least one of the partition format combinations that is configured by RRC to the UE through DCI transmitted via the common group PDCCH.
[0302] FIG. 16 is a block diagram illustrating a structure of a base station (BS) 105 and a UE 110 in a wireless communication system 100 according to an embodiment of the present invention. BS 105 can be referred to as an eNB or a gNB. UE 110 can be referred to as a user terminal.
[0303] Although a BS 105 and UE 110 are illustrated to simplify wireless communication system 100, wireless communication system 100 may include one or more BSs and / or one or more UEs.
[0304] BS 105 may include a transmit (Tx) data processor 115, a symbol modulator 120, a transmitter 125, a transmit / receive antenna 130, a processor 180, a memory 185, a receiver 190, a symbol demodulator 195 and a receiving data processor (Rx) 197. The UE 110 may include a data processor Tx 165, a symbol modulator 170, a transmitter 175, a transmitting antenna /
Petition 870190015766, of 02/15/2019, p. 81/109
63/67 reception 135, processor 155, memory 160, receiver 140, symbol demodulator 155 and data processor Rx 150. In FIG. 12, although an antenna 130 is used for BS 105 and an antenna 135 is used for UE 110, each of BS 105 and UE 110 can also include a plurality of antennas as needed. Therefore, BS 105 and UE 110 according to the present invention support a MIMO (Multiple Input and Multiple Output) system. BS 105 according to the present invention can support both a single user MIMO scheme (SU-MIMO) and a multiple user MIMO scheme (MU-MIMO).
[0305] In the downlink, the Tx 115 data processor receives traffic data, formats the received traffic data, encodes the formatted traffic data, merges the encoded traffic data and modulates the merged data (or performs mapping of symbols in the data interleaved) in order to provide modulation symbols (ie data symbols). The symbol modulator 120 receives and processes data symbols and pilot symbols in order to provide a flow of symbols.
[0306] The symbol modulator 120 multiplexes data and pilot symbols, and transmits the multiplexed data and pilot symbols to transmitter 125. In this case, each transmission symbol (Tx) can be a data symbol, a pilot symbol or a value of a zero sign (null sign). In each symbol period, the pilot symbols can be transmitted successively during each symbol period. The pilot symbols can be an FDM symbol, an OFDM symbol, a time division multiplexing (TDM) symbol or a code division multiplexing (CDM) symbol.
[0307] Transmitter 125 receives a stream of symbols, converts received symbols into one or more analog signals and additionally adjusts one or more analog signals (for example, amplification, filtering and conversion
Petition 870190015766, of 02/15/2019, p. 82/109
64/67 ascending frequency of analog signals), so that it generates an appropriate downlink signal for data transmission through an RF channel. Subsequently, the downlink signal is transmitted to the UE via antenna 130.
[0308] The configuration of the UE 110 will be described in detail below. Antenna 135 of UE 110 receives a DL signal from BS 105 and transmits the DL signal to receiver 140. Receiver 140 performs the adjustment (for example, filtering, amplification and frequency downward conversion) of the received DL signal, and digitizes the signal adjusted to obtain samples. Symbol demodulator 145 demodulates received pilot symbols and provides demodulated result to processor 155 to perform channel estimation.
[0309] Symbol demodulator 145 receives a frequency response estimate value for processor downlink 155, demodulates received data symbols, obtains data symbol estimation values (indicating estimated values of transmitted data symbols) and provides the data symbol estimation values for the Rx 150 data processor. The Rx 150 data processor performs demodulation (that is, symbol demapping) of data symbol estimation values, de-interleaves the demodulated result, decodes the deinterleaved result and retrieves transmitted traffic data.
[0310] The processing of the symbol demodulator 145 and the data processor Rx 150 is complementary to that of the symbol modulator 120 and the data processor Tx 115 in BS 205.
[0311] The UE 110's Tx 165 data processor processes uplink traffic data and provides data symbols. The symbol modulator 170 receives and multiplexes data symbols and modulates multiplexed data symbols, such that it can provide a stream of symbols to transmitter 175. The transmitter
Petition 870190015766, of 02/15/2019, p. 83/109
65/67
175 obtains and processes the stream of symbols to generate an uplink signal (UL) and the UL signal is transmitted to BS 105 via antenna 135. The UE / BS transmitter and receiver can be implemented as a single radio frequency unit (RF).
[0312] BS 105 receives the UL signal from UE 110 through antenna 130. The receiver processes the received UL signal to obtain samples. Subsequently, the symbol demodulator 195 processes the symbols and provides pilot symbols and estimation values for data symbols received via uplink. The Rx 197 data processor processes the estimated value of the data symbol and retrieves the traffic data received from the UE 110.
[0313] A 155 or 180 processor from UE 110 or BS 105 controls or indicates UE 110 or BS 105 operations. For example, processor 155 or 180 from UE 110 or BS 105 controls, adjusts and manages UE 210 operations. or BS 105. Each processor 155 or 180 can be connected to a memory unit 160 or 185 to store code and program data. Memory 160 or 185 is connected to processor 155 or 180, so that it can store the operating system, applications and general files.
[0314] Processor 155 or 180 can also be referred to as a controller, a microcontroller), a microprocessor, a microcomputer, etc. Meanwhile, the 155 or 180 processor can be implemented by various means, for example, hardware, firmware, software or a combination thereof. In a hardware configuration, methods according to the modalities of the present invention can be implemented by processor 155 or 180, for example, one or more application-specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing (DSPDs), programmable logic devices (PLDs), field programmable port arrangements (FPGAs), processors, controllers, microcontrollers,
Petition 870190015766, of 02/15/2019, p. 84/109
66/67 microprocessors, etc.
[0315] In a firmware or software configuration, the methods according to the modalities of the present invention can be implemented in the form of modules, procedures, functions, etc., that perform the functions or operations described above. The firmware or software implemented in the present invention can be contained in processor 155 or 180 or in memory unit 160 or 185, so that it can be driven by processor 155 or 180.
[0316] Radio interface protocol layers between UE 110, BS 105, and a wireless communication system (ie network) can be classified into a first layer (L1 layer), a second layer (L2 layer) ) and a third layer (L3 layer) based on the bottom three layers of the Open System Interconnection (OSI) reference model widely known in communication systems. A physical layer belonging to the first layer (L1) provides an information transfer service through a physical channel. A RRC layer (Radio Resource Control) belonging to the third layer (L3) controls the radio resources between the UE and the network. The UE 110 and BS 105 can exchange RRC messages with each other via the wireless communication network and the RRC layer.
[0317] The above mentioned modalities correspond to combinations of elements and characteristics of the present invention in prescribed forms. And it is possible to consider that the respective elements or resources are selective, unless they are explicitly mentioned. Each of the elements or features can be implemented in a way that cannot be combined with other elements or features. In addition, it is possible to implement a modality of the present invention by combining elements and / or characteristics together. A sequence of operations explained for each embodiment of the present invention can be modified. Some configurations or characteristics of a modality
Petition 870190015766, of 02/15/2019, p. 85/109
67/67 can be included in another modality or can be replaced by corresponding configurations or characteristics from another modality. And, apparently, it is understandable that a modality is configured by combining claims that cannot be explicitly cited in the attached claims together or that can be included as new claims for amendments after filing the application.
[0318] Although the present invention has been described and illustrated here with reference to its preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention. Thus, it is intended that the present invention covers the modifications and variations of this invention that are within the scope of the appended claims and their equivalents [Industrial Applicability] [0319] As described above, the present invention can be applied to various communication systems without thread

权利要求:
Claims (15)
[1]
1. Method for receiving downlink control information (DL) by a user equipment (UE) in a wireless communication system, the method FEATURED by the fact that it comprises:
receive the first information regarding a reference sub carrier spacing (SCS);
receiving DL control information through a common EU group physical downlink control channel (PDCCH);
obtain, from the DL control information, second information regarding a partition format that is related to the reference SCS; and based on a first SCS used by the UE being different from the reference SCS, apply the partition format to a plurality of partitions of the first SCS, where the plurality of partitions of the first SCS corresponds to a partition of the reference SCS.
[2]
2. Method according to claim 1, CHARACTERIZED by the fact that receiving the first information regarding the reference SCS comprises:
receive the first information in relation to the reference SCS via upper layer signaling.
[3]
3. Method according to claim 1, CHARACTERIZED by the fact that the reference SCS is equal to or less than the first SCS of the UE, and in which a time duration of a partition of the reference SCS equal to or greater than a duration of time of each of the plurality of partitions of the first UE SCS.
[4]
4. Method according to claim 3, CHARACTERIZED by the fact that the first SCS of the UE is M times larger than the reference SCS, and in which the plurality of partitions of the first SCS consists of M contiguous partitions of the first SCS that correspond to the reference SCS partition.
Petition 870190015766, of 02/15/2019, p. 104/109
2/5
[5]
5. Method according to claim 4, CHARACTERIZED by the fact that the partition of the reference SCS comprises a first plurality of symbols, wherein each of the plurality of partitions of the first SCS of the UE comprises a second plurality of symbols, in which M contiguous symbols of the first SCS correspond to a symbol of the reference SCS and where applying the partition format to the plurality of partitions of the first SCS comprises, for each of the first plurality of symbols in the partition of the reference SCS:
determine, based on the second information in relation to the partition format, that the reference SCS symbol corresponds to a downlink (D), uplink (U) or flexible (X) symbol; and determining that the contiguous M symbols of the first SCS each correspond to D, U or X.
[6]
6. Method according to claim 1, CHARACTERIZED by the fact that the second information referring to the partition format indicates at least one partition format combination configured in the UE.
[7]
7. Method according to claim 6, CHARACTERIZED by the fact that the UE is configured with a plurality of frequency bands; and wherein each of the format combinations of at least one partition comprises a plurality of partition formats for the plurality of frequency bands.
[8]
8. Method according to claim 7,
CHARACTERIZED by the fact that each of the at least one partition format combination comprises (i) a partition format for a DL frequency band and (ii) a partition format for a
Petition 870190015766, of 02/15/2019, p. 105/109
3/5 UL frequency, or where each of the at least one partition format combination comprises (I) a partition format for a new radio access technology (NR) frequency band and (li) a partition to a long-term evolution frequency band (LTE).
[9]
9. Method according to claim 6, CHARACTERIZED by the fact that the combination of at least one partition formation configured in the UE is obtained through upper layer signaling, and in which the combination of at least one partition formation is a subset of a plurality of partition format combinations that are supported in the wireless communication system.
[10]
10. Method according to claim 1, CHARACTERIZED by the fact that the application of the partition format, which is related to the reference SCS, for the plurality of partitions of the first SCS comprises:
convert the partition format into a first partition format related to the first UE SCS.
[11]
11. Method of transmitting downlink control information (DL) by a base station (BS) in a wireless communication system, the method CHARACTERIZED by the fact that it comprises:
transmit, to a user equipment (UE), the first information regarding a reference sub carrier spacing (SCS);
generate DL control information that comprises second information regarding a partition format related to the reference SCS; and transmit, through a common EU group physical downlink control channel (PDCCH), the DL control information to an EU group comprising the UE, where, in a state where the reference SCS is different from one
Petition 870190015766, of 02/15/2019, p. 106/109
4/5 first SCS used by the UE, the BS indicates the partition format for the UE based on the reference SCS.
[12]
12. Method according to claim 11, CHARACTERIZED by the fact that the reference SCS is equal to or less than the first SCS of the UE, and in which a time duration of a partition of the reference SCS equal to or greater than a duration of time of a partition of the first SCS of the UE.
[13]
13. The method of claim 11,
CHARACTERIZED by the fact that the partition format indicates, for each symbol, a plurality of symbols included in a partition corresponding to the partition format, whether the symbol corresponds to downlink (D), uplink (U) or flexible (X); and where the second information regarding the partition format indicates at least one partition formation combination configured in the UE.
[14]
14. User equipment (UE) configured to receive downlink control (DL) information in a wireless communication system, the UE FEATURED by the fact that it comprises:
a receiver;
at least one processor; and at least one computer memory operably connectable to at least one processor and storing instructions that, when executed, cause at least one processor to perform operations comprising:
receive, through the receiver, the first information regarding a reference sub carrier spacing (SCS); receiving, through the receiver, the DL control information through a common EU group downlink control channel (PDCCH);
obtain, from the DL control information, second information regarding a partition format that is related to the reference SCS; and
Petition 870190015766, of 02/15/2019, p. 107/109
5/5 based on a first SCS used by the UE being different from the reference SCS, apply the partition format to a plurality of partitions from the first SCS, where the plurality of partitions from the first SCS corresponds to a partition from the reference SCS .
[15]
15. Base station (BS) configured to transmit downlink control information (DL) in a wireless communication system, BS FEATURED by the fact that it comprises:
a transmitter;
at least one processor; and at least one computer memory operably connectable to at least one processor and storing instructions that, when executed, cause at least one processor to perform operations comprising:
transmit, through the transmitter and to a user equipment (UE), the first information regarding a reference sub carrier spacing (SCS);
generate DL control information that comprises second information regarding a partition format related to the reference SCS; and transmit, through the transmitter and through a common EU group downlink control channel (PDCCH), the DL control information to an UE group comprising the UE, where in a state in which the reference SCS is different of a first SCS used by the UE, the at least one processor indicates the partition format for the UE based on the reference SCS.

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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US20090067377A1|2007-08-15|2009-03-12|Motorola, Inc.|Medium access control frame structure in wireless communication system|

---

KR20090105789A|2008-04-02|2009-10-07|엘지전자 주식회사|Method of transmitting a reference signal|

---

CN103444106B|2011-03-18|2016-05-11|Lg电子株式会社|The method sending control information in wireless communication system and equipment thereof|

---

JP6007179B2|2011-08-05|2016-10-12|パナソニック インテレクチュアル プロパティ コーポレーション オブ アメリカＰａｎａｓｏｎｉｃ Ｉｎｔｅｌｌｅｃｔｕａｌ Ｐｒｏｐｅｒｔｙ Ｃｏｒｐｏｒａｔｉｏｎ ｏｆ Ａｍｅｒｉｃａ|Terminal, base station, transmission method and reception method|

---

KR20130039638A|2011-10-12|2013-04-22|에릭슨 엘지 주식회사|Method and apparatus for transmitting downlink control information|

---

KR102246558B1|2014-02-28|2021-04-30|엘지전자 주식회사|Method and apparatus for generating signal for low latency in wireless communication system|

---

WO2016004634A1|2014-07-11|2016-01-14|Mediatek Singapore Pte. Ltd.|Method for enb, ue uplink transmission and reception|

---

US20160219584A1|2015-01-22|2016-07-28|Texas Instruments Incorporated|High performance nlos wireless backhaul frame structure|

---

CN107210810B|2015-02-11|2020-09-29|苹果公司|Apparatus, system, and method for using a unified flexible 5G air interface|

---

US20160337105A1|2015-05-14|2016-11-17|Interdigital Technology Corporation|Channel and noise estimation for downlink lte|

---

KR20170007175A|2015-07-10|2017-01-18|한국전자통신연구원|Low latency transmission method and apparatus|

---

US10205581B2|2016-09-22|2019-02-12|Huawei Technologies Co., Ltd.|Flexible slot architecture for low latency communication|

---

US10925079B2|2016-10-27|2021-02-16|Kt Corporation|Method and device for scheduling uplink signal and downlink data channel in next generation wireless network|

---

KR102164967B1|2017-01-06|2020-10-13|한국전자통신연구원|Method and apparatus for transmitting and receiving control channel in communication system|

---

US11147051B2|2017-02-06|2021-10-12|Apple Inc.|Transmission of group common PDCCH for NR |

---

KR20180091527A|2017-02-07|2018-08-16|삼성전자주식회사|Method and apparatus for transmission and reception of control and data in wireless comunication system|

---

CN110463305A|2017-03-23|2019-11-15|松下电器（美国）知识产权公司|Base station, terminal and communication means|US11265727B2|2017-03-22|2022-03-01|Panasonic Intellectual Proper ty Corporation of America|Base station and communication method|

---

WO2018203814A1|2017-05-04|2018-11-08|Telefonaktiebolaget Lm Ericsson |Wireless device, network node, and methods performed thereby for handling a communication of blocks of physical channels or signals|

---

CN108964853A|2017-05-18|2018-12-07|华为技术有限公司|A kind of indicating means of time slot, access network equipment and user equipment|

---

JPWO2019030925A1|2017-08-10|2020-08-20|株式会社Ｎｔｔドコモ|User terminal and wireless communication method|

---

BR112020009625A2|2017-11-17|2020-11-03|Guangdong Oppo Mobile Telecommunications Corp., Ltd.|method for indicating a partition format, network device and terminal|

---

CN109802816B|2017-11-17|2021-01-29|华为技术有限公司|Information transmission method and equipment|

---

ES2882594T3|2018-03-28|2021-12-02|Asustek Comp Inc|Method and apparatus for the determination of the interval format in a wireless communication system|

---

CN112997558A|2018-11-01|2021-06-18|夏普株式会社|User equipment, base station and method|

---

US11140722B2|2018-11-01|2021-10-05|Ofinno, Llc|Pathloss measurement in multiple cells|

---

EP3681233A1|2019-01-10|2020-07-15|Panasonic Intellectual Property Corporation of America|Transceiver device and scheduling device|

---

CN111988848A|2019-05-22|2020-11-24|华为技术有限公司|Method and communication device for time slot format indication|

---

WO2021056383A1|2019-09-27|2021-04-01|Oppo广东移动通信有限公司|Wireless communication method, terminal device and network device|

---

CN110839296B|2019-11-29|2021-10-22|惠州Tcl移动通信有限公司|Network resource scheduling method, device, storage medium and mobile terminal|

法律状态:
2021-10-05| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

---

申请号 | 申请日 | 专利标题

---

US201762476682P| true| 2017-03-24|2017-03-24|

---

US201762500557P| true| 2017-05-03|2017-05-03|

---

US201762596785P| true| 2017-12-09|2017-12-09|

---

US201862616450P| true| 2018-01-12|2018-01-12|

---

US201862621495P| true| 2018-01-24|2018-01-24|

---

PCT/KR2018/003465|WO2018174653A1|2017-03-24|2018-03-23|Method of transmitting or receiving signals in wireless communication system and apparatus therefor|

---