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    • 专利摘要:
    method for detecting downlink control information and device for detecting downlink control information the present invention provides a method and a device for detecting downlink control information, which refer to the field of communication. the method includes: during cross-carrier programming, the user equipment (eu) determines a search space to monitor a physical downlink control channel (pdcch) according to the number of downlink component carriers in a pdcch monitoring set and the number of downlink component carriers in a eu dl component carrier set.
    公开号:BR112012016267B1
    申请号:R112012016267-5
    申请日:2010-06-30
    公开日:2021-02-23
    发明作者:Bo Dai;Xin Wu;Ping Zeng;Zhisong Zuo
    申请人:Zte Corporation;
    IPC主号:
    专利说明:

    TECHNICAL FIELD
    The present invention relates to the field of communication and, in particular, to a method and device for detecting downlink control information. BACKGROUND OF RELATED TECHNIQUE
    The radio frame in the long-term evolution system (LTE) includes frame structures of frequency division duplex mode (FDD) and time division duplex mode (TDD). The frame structure of the FDD mode is as shown in Figure 1, in which a 10 ms radio frame is composed of twenty intervals, the length of which is 0.5 ms and is numbered from 0 to 19, and intervals 2i and 2i + l form a subframe i, the length of which is 1 ms. The frame structure of the TDD mode is as shown in Figure 2, in which a 10 ms radio frame is composed of two frame halves, 20 of which are 5 ms in length, a half frame includes 5 subframes , the length of which is 1 ms, and subframe i is defined as 2 intervals 2i and 2i + 1, the length of which is 0.5 ms. In the two frame structures above, as for the normal cyclic prefix 25 (normal CP), a range includes 7 symbols, in which the length of the same is 66.7 us, with the CP length of the first symbol being 5.21 us, and the CP length of the remaining 6 symbols is 4.69 us; and, for an extended cyclic prefix (extended CP), a range includes 6 30 symbols, and the CP length of all symbols is 16.67 us.
    The release number of corresponding LTE for release 8 (R8), and release correspondents added to the release number of release 9 (R9), as well as the subsequent advanced LTE, its release number is release 10 (RIO). The three physical downlink control channels are defined in LTE: physical control indicator channel (PCFICH), physical hybrid automatic retransmission request channel (PHICH), and physical downlink control channel (PDCCH).
    In this case, the information carried by the PCFICH is used to indicate the number of orthogonal frequency division multiplexing symbols (OFDM) of the PDCCH transmitted in a subframe and are sent in the first OFDM symbol of the subframe, and its frequency location is determined by the system downlink bandwidth and the cell ID (id).
    The PHICH is used to carry acknowledgment / non-acknowledgment feedback (ACK / NACK) information from the uplink transmission data. The location of time frequency and PHICH number can be determined by the system message and cell identification on a physical broadcast channel (PBCH) of a downlink carrier on which the PHICH is located.
    The PDCCH is used to carry downlink control (DCI) information, which includes uplink / downlink programming information and uplink power control information. DCI formats are classified as: DCI format 0, DCI format 1, DCI format la, DCI format 1b, DCI format 1c, DCI format 1 d, DCI format 2, DCI format 2a, DCI format 3, DCI format 3a and so on onwards, where DCI 0 format is used to indicate the programming of the physical uplink shared channel (PUSCH);
    DCI format 1, DCI format la, DCI format lb, DCI format lc, DCI format ld are used for unequal modes of programming a PDSCH codeword; The DCI 2 format, the DCI 2a format, and the DCI 2b format are used for unequal space division multiplexing modes;
    The DCI 3 format and the DCI 3a format are used for unequal modes of physical uplink control (PUCCH) and PUSCH channel power control instructions.
    In this case, the DCI 3 and 3a format sizes are consistent with the DCI 0 format. In this case, in the DCI 3 format, two continuous bits are used to indicate the PUCCH and PUSCH power control transmission (TPC) commands, a high-layer signaling (TCP index) designates the starting position of a user's TCP command, while in DCI format 3a, bit 1 is used to indicate PUCCH and PUSCH power control transmission (TPC) commands, and the high-layer signaling (TCP index) designates the starting position of a user's TCP command.
    In particular, the DCI 3 format uses 2 bits to transmit the TCP command to PUCCH and PUSCH, and the following information is indicated by the DCI 3 format: TCP command 1, TCP command 2, ..., TCP command n In this case,
    o format is equal to size before DCI format 0 add cyclic redundancy check (CRC), which includes any bits added, and LJ represents round down. And, the TCP parameter index provided by the high-layer signaling is used to assign the TCP command index to a certain user. If
    then a bit 0 will be added in DCI 3 format.
    In particular, the DCI 3a format uses bit 1 to transmit the TCP command to PUCCH and PUSCH, and the following information is indicated by the DCI 3a format: TCP 1 command, TCP 2 command, ..., TCP M 5 command In this case , ^ = iformatoz Aormato £ equal to the size before the DCI 0 format add CRC, which includes any added bits, and the TCP parameter index provided by the high layer signaling is used to assign the TCP command index to a certain user. 10 The physical resources transmitted by the physical downlink control channel (PDCCH) are in the control channel element (CCE) unit, and the size of a CCE is 9 resource element groups (REG), that is, 36 resource elements (RE), and a PDCCH can occupy 15 1, 2, 4, or 8 CCES. As well as the sizes of these four types of PDCCH that occupy 1, 2, 4, or 8 CCES, three aggregations are used, that is, the PDCCH that occupies 1 CCE can start from any CCE location; the PDCCH that occupies 2 CCE starts from the same CCE location; the PDCCH that occupies 4 20 CCE starts from the CCE site which is an integral multiple of 4; and the PDCCH that occupies 8 CCE starts from the CCE location, which is an integral multiple of 8.
    Each aggregation level defines a search space, which includes common search space and search space for 25 specific user equipment (specific UE). The CCE number of the entire search space is determined by the number of OFDM symbols occupied by the control area indicated by the PCFICH in each downlink subframe and the number of PHICH groups. The UE performs blind detection at all 30 possible PDCCH code rates according to the DCI format of the transmission modes in the search space. In the k-th subframe, the control domain that carries the PDCCH is composed of a group of CCE'k CCE N -1 numbered from 0 to CCE '*. The UE must detect a group of PDCCH candidates in each non-discontinuous (non-DRX) subquedric as well as acquire control information, and detection refers to decoding the PDCCHs in the group according to the entire DCI format to be detected. The PDCCH candidates to be detected are defined in the form of a search space, and just like the aggregation level L and fl 2 4 8) S (L) i '''>, the search space k is defined by a group of PDCCH candidates. The CCE corresponding to candidate M of Sw PDCCH in search space k is defined according to the following formula:
    where i = m = -l, Af (L) is the number of S (L) PDCCH candidates to be detected in the search space k. y = o T As for the common search space, k, L takes the values of 4 and 8.
    As for the specific UE search space, L takes the values of 1, 2, 4, and 8.
    in cue Ki = "RNTI * 0 .4 = 39827 77 = 65537 ^ = L" S / 2J «s is an interval number in a radio frame. RNTI and a corresponding RNTI (temporary radio network identifier).
    The UE must detect a common search space with its aggregation levels, being 4 and 8 respectively and a specific UE search space with its aggregation levels, being 1, 2, 4 and 8 respectively, and the common search space and specific UE search space can be overlapped. The particular number of detections and the corresponding search space are as shown in TABLE 1: Table 1
    The UE is configured in a semi-static manner to receive the transmission of PDSCH data according to the PDCCH indication of the specific UE search space based on one of the following transmission modes by means of a high-layer signaling: Mode 1 : Single antenna port; port 0 Mode 2: Transmission diversity Mode 3: Open loop spatial multiplexing Mode 4: Closed loop spatial multiplexing Mode 5: Multiuser MIMO Mode 6: Closed loop hierarchy = precoding 1 Mode 7: single antenna port; port 5 If the UE is configured by the high layer to decode the PDCCH using cyclic redundancy check (CRC) encrypted by the temporary cell radio network identifier (C-RNTI), then the UE must decode the PDCCH and all relevant PDSCHS according to the corresponding combination defined in TABLE 2: TABLE 2

    If the UE is configured by the high layer to perform PDCCH decoding by using the CRC encrypted by the semi-persistent programmed cell radio network identifier (SPS C-RNTI), 5 then the UE must decode the PDCCH and all the relevant PDSCHS according to the corresponding combination defined in table 3: TABLE 3

    If the UE is configured by the high layer to perform PDCCH decoding by using the CRC encrypted by the transmit power control - PUCCH - temporary cell radio network identifier 5 (TPC-PUCCH-RNTI), then the UE must decode the PDCCH according to the corresponding combination defined in TABLE 4: TABLE 4

    If the UE is configured by the high layer to perform PDCCH decryption by using the CRC encrypted by the PUSCH transmission power control - temporary cell radio network identifier (TPC-PUSCH-RNTI), then the UE must decode o PDCCH according to the corresponding combination defined in TABLE 5: TABLE 5

    Since the advanced LTE network needs to be able to access LTE users, its operating frequency band needs to cover the current LTE frequency band, and there is already a 100 mhz non-continuous frequency spectrum bandwidth that can be used. allocated in that bandwidth, a direct technology to be solved by advanced LTE is to aggregate many carriers of continuous components (frequency spectrum) distributed in a different frequency from the bands by using carrier aggregation technology to form a bandwidth of 100mhz that can be used by advanced LTE. That is, just like the aggregate frequency spectrum, it is divided into N component carriers (frequency spectrum), and the frequency spectrum on each component carrier (frequency spectrum) is continuous.
    3GPP provides a PDCCH monitoring set (PDCCH monitoring set), which includes downlink component carriers and belongs to a UE DL component carrier set. User H must monitor the PDCCH on that downlink component carrier. In an advanced LTE system, the use of carrier aggregation allows a downlink component carrier to match a plurality of component carrier uplinks, which is different from the situation where only one downlink carrier matches one uplink carrier in the LTE system. And, the method for blind detection of PDCCH is different as well. In addition, there is still no blind detection method for PDCCH in the related technique, which brings problems for practical application. SUMMARY OF THE INVENTION
    The method and device for detecting downlink control information provided by the present invention is used to manage the blind detection of PDCCH in the carrier aggregation system.
    In order to achieve the purpose of the invention described above, the present invention provides the following technical solution: a method for detecting downlink control information comprises: during cross-carrier programming, the user equipment (UE) determines a space of search to monitor a physical downlink control channel (PDCCH) according to the number of downlink component carriers in a UE DL component carrier set and the number of downlink component carriers in a set of PDCCH monitoring.
    Preferably, the method described above also has the following characteristics: the step of determining the search space to monitor the PDCCH comprises: whether the number of downlink component carriers in the PDCCH monitoring set and the number of component downstream carriers downlink in the UE DL component carrier set are the same, the search space for the user equipment to monitor the PDCCH is consistent with that for single carrier programming; and if the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set are uneven, the search space for the user equipment to monitor the PDCCH on carriers that can perform cross carrier programming will be expanded. Preferably, the method described above also has the following characteristics: the expanded search space is the specific user search space. Preferably, the method described above also has the following characteristics: the equal search space is extended for each bearer of downlink component that performs the cross bearer programming in the PDCCH monitoring set. Preferably, the method described above also has the following characteristics: the expanded search space is determined by the increased number of monitoring times for each downlink component carrier that can perform cross-carrier programming, in which the expanded number of times The monitoring rate is determined according to the difference between the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set. Preferably, the method described above also has the following characteristics: the increased number of monitoring times is
    J, where, M is the number of downlink component carriers in the EU DL component carrier set, 1 is the number of downlink component carriers in the PDCCH monitoring set, P is the number of carriers downlink component that can perform cross carrier programming in the PDCCH monitoring set, and N is the maximum number of monitoring times for each downlink component carrier when cross carrier programming is not performed. Preferably, the method described above also has the following characteristics: allocate the search space that corresponds to the increased number of monitoring times for each bearer component member that can carry out cross bearer programming is implemented through the following method: select H aggregation levels from aggregation levels 1, 2, 4 and 8 in the search space of the specific UE, and add PDCCH A candidates at each selected aggregation level respectively,
    where He {l, 2,3,4}, B is the number of downlink control information formats (DCI format) under each transmission mode. Preferably, the method described above also has the following characteristics: if the downlink component carrier A can perform cross carrier programming, the user equipment detects the downlink control information that corresponds to all or part of the 5 carriers downlink component carriers that can be programmed by the downlink component carrier a in the extended search space on the downlink component carrier A. Preferably, the method described above also has the following characteristics: link control information downlink that corresponds to all or part of the downlink component carriers that can be programmed by the downlink component carrier A are sent by the base station in the expanded search space on the downlink component carrier A. Preferably, the method described above also has the following face Features: If the downlink component carrier 2 0 B can perform cross carrier programming and can program downlink component carriers H, the search space of the downlink component carrier B is expanded to the search space H, where there is a one-to-one correspondence between the search space H and 25 bearers of the downlink component H. Preferably, the method described above also has the following characteristics: the locations of the search space H are continuous, or the search space h locations are produced according to a downlink component carrier index that matches the search space. Preferably, the method described above also has the following characteristics: the user equipment detects the downlink control information of the downlink component carrier that corresponds to the search space in the expanded search space. Preferably, the method described above also has the following characteristics: the downlink control information of the downlink component carrier Y is sent by a base station through the search space that corresponds to the downlink component carrier Y, where the downlink component carrier Y is any one of the downlink component carriers H. A device for detecting downlink control information applied to the user equipment is configured to: during cross carrier programming, determine a search space to monitor a physical downlink control (PDCCH) channel according to the number of downlink component carriers in a PDCCH monitoring set and the number of downlink component carriers in a set of EU DL component carrier. Preferably, the device also has the following characteristics: the device is configured for: if the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the DL component carrier set of UE are the same, the search space is adjusted to monitor the PDCCH to be consistent with that for single carrier programming; and if the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set are uneven, the search space for monitoring the PDCCH is expanded on carriers that can perform cross carrier programming. Preferably, the device also has the following characteristics: the expanded search space is the specific user search space. Preferably, the device also has the following characteristics: the device is configured to: expand equal search space for each downlink component carrier that performs cross carrier programming in the PDCCH monitoring set. Preferably, the device also has the following characteristics: the expanded search space is determined by the increased number of monitoring times for each downlink component carrier that can perform cross-carrier programming, in which the increased number of monitoring times is determined according to the difference between the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set. Preferably, the device also has the following characteristics: the increased number of monitoring times is
    where, M is the number of downlink component carriers in the EU DL component carrier set, 1 is the number of downlink component carriers in the PDCCH monitoring set, P is the number of component carriers downlink that can perform cross carrier programming in the PDCCH monitoring set, and N is the maximum number of monitoring times for each downlink component carrier when cross carrier programming is not performed. Preferably, the device also has the following characteristics: the device is configured to: allocate the search space that corresponds to the expanded number of monitoring times for each said downlink component carrier that can carry out cross carrier programming is deployed through using the following method: select aggregation levels H from aggregation levels 1, 2, 4 and 8 in the search space of the specific UE, and add PDCCH A candidates in each selected aggregation level respectively,
    where He {l, 2,3,4}, B is the number of downlink control information formats (DCI format) under each transmission mode. Preferably, the device also has the following characteristics: the device is also configured for: if the downlink component carrier A can perform cross-carrier programming, downlink control information that corresponds to all or part of the downlink component carriers that can be programmed by the downlink component carrier A in the extended search space on the downlink component carrier A. Preferably, the device also has the following characteristics: downlink control information that correspond to all or part of the downlink component carriers that can be programmed by the downlink component carrier and are sent by the base station in the extended search space of the downlink component carrier A. Preferably, the device also has the following features: the di The device is configured for: if the downlink component carrier B can carry out cross carrier programming and can program downlink component carriers H, the search space of the downlink component carrier B for space is expanded search H, where there is a one-to-one correspondence between the H search space and the downlink H component carriers. Preferably, the device also has the following characteristics: the locations of the H search space are continuous, or the search space locations H are produced according to a downlink component carrier index that corresponds to the search space. Preferably, the device also has the following characteristics: detecting the downlink control information of the downlink component carrier that corresponds to the search space in the expanded search space. Preferably, the device also has the following characteristics: the downlink control information of the downlink component carrier Y is sent by a base station through the search space that corresponds to the downlink component carrier Y, where the bearer of downlink component Y is any one of said bearer of downlink component H.
    In the technical solution provided by the present invention, the search space for monitoring the PDCCH is determined according to the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the carrier set. of EU DL component. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic diagram of the frame structure in an FDD mode in the related art; Figure 2 is a schematic diagram of a frame structure in a TDD manner in the related art; and Figure 3 is a flow chart of a method for managing the downlink control information provided by the present invention. PREFERENTIAL MODALITIES OF THE PRESENT INVENTION
    Hereinafter, the technical solution provided by the modalities of the present invention will be described further in conjunction with the accompanying drawings.
    In the related technique, in LTE, the user needs to monitor the PDCCH on a carrier, however, in advanced LTE, the user needs to perform PDCCH blind detection on all downlink component carriers in the PDCCH monitoring set.
    In RIO, the number of downlink component carriers in the UE DL component carrier set is M, the number of downlink component carriers that requires the user to perform blind detection on the same in the PDCCH monitoring set is 1, in the PDCCH monitoring set, the number of downlink component carriers that can carry out cross carrier programming is p. When not doing cross carrier programming, the maximum number of blind detections for each downlink component carrier is N, where the preferred value of N is 44 or 60.
    When cross carrier programming is required, the maximum number of blind detections for each downlink component carrier in the PDCCH monitoring MxN set is

    Hereinafter, the method for detecting downlink control information will be described, according to WO 2010/149106 Al shown in figure 3: Step 301: the downlink component carrier numbers in the EU DL component carrier set and in the set PDCCH monitoring systems are acquired. Step 302: it is judged whether the number of downlink component carriers in the EU DL component carrier set and the number of downlink component carriers in the PDCCH monitoring set are the same;
    If they are the same, that is, if the EU DL component carrier set and the PDCCH monitoring set are equal in size, the maximum number of blind detections for each component carrier in the PDCCH monitoring set is the same as when cross-carrier programming is not performed, which is equal to N, the blind detection of UE in PDCCH is managed by the specific UE search space in the related technique, which does not need to be described in this document. If unequal, proceed to step 303. Step 303: the search space to monitor the PDCCH is expanded.
    The following modalities are described taking the expansion of the search space of the specific UE as an example: MODE I If the UE component carrier set and the PDCCH monitoring set are unequal in size, compared to the maximum number of blind detections when cross carrier programming is not performed, the maximum number of blind detections for each component carrier performing cross carrier programming in the PDCCH monitoring set is increased by

    In this document, the UE that increases the number of blind detections is equivalent to expanding the PDCCH blind detection search space. Since the number of blind detections is increased
    achieved by expanding the search space for different levels of aggregation under the search space of the specific UE.
    In the present invention, the following configurations will exist on how to add the expanded number of
    for these aggregation levels by expanding the search space for aggregation levels H under the search space of the specific UE: CONFIGURATION I: When the value of is 4, the maximum number of blind detections for each component carrier that can perform programming cross-carrier in the monitoring set
    of PDCCH is increased by
    they will be allocated to four aggregation levels under the specific UE search space, that is, each aggregation level whose expanded number of blind detections is allocated to increase
    PDCCH candidates based on the failure to perform the 10 cross-carrier programming originally, where H is equal to 4, and B is the number of DCI format included under each transmission mode. As shown in table 6: TABLE 6
    CONFIGURATION II: When the value of H is 3, the increased number of blind detections
    will be allocated to three aggregation levels under the specific UE search space, that is, each aggregation level whose expanded number of blind detections is allocated to increase

    PDCCH candidates based on the failure to perform cross-carrier programming originally, where H is equal to 3, and b is the number of 5 DCI formats included under each transmission mode. These three levels of aggregation can be a combination of any three among aggregation levels 1, 2, 4 and 8, for example, which are allocated to aggregation levels 1, 2 and 4, as shown in table 7: TABLE 7
    CONFIGURATION III: When the value of H is 2, the increased number of blind detections
    will be allocated in two levels of aggregation under the search space of the specific UE, that is, each level of aggregation which is the expanded number of blind detections is allocated to increase

    PDCCH candidates based on the failure to perform cross-carrier programming originally, where H is equal to 2, and B is the DCI format number included under each transmission mode. These two 5 levels of aggregation can be a combination of any two levels of aggregation from 1, 2, 4 and 8, for example, which are allocated to levels of aggregation 1 and 2, as shown in TABLE 8:
    CONFIGURATION IV: When the value of H is 1, the increased number of blind detections
    will be allocated to an aggregation level under the specific UE search space, that is, each aggregation level that increased the number of blind detections is allocated to increase

    PDCCH candidates based on not performing cross-carrier programming originally, where H is equal to 1, and B is the number of DCI formats included under each transmission mode. An aggregation level can be any of aggregation levels 1, 2, 4 and 8, for example, which is allocated to aggregation level 1, as shown in TABLE 9: TABLE 9

    When the method mentioned above is used to expand the search space, if the downlink component carrier A can perform cross-carrier programming, the user equipment detects the downlink control information that corresponds to all or part of the downlink component carriers that can be programmed by the downlink component carrier a in the extended search space of the downlink component carrier A.
    In particular, the downlink component carrier A must detect all downlink control information that can be programmed in the extended search space. For example, M = 4, L = 2, P = 2, the downlink component carriers are A, B, C, and D respectively, where A and B can carry out cross carrier programming. Assuming that when A's search space is for single carrier programming, the size of the search space is X. When cross-carrier programming is performed, A can program C and D, and the search space of A is expanded as 2X, and the expanded search space 2X is the search space of A, C and D, where the expanded search space is X. When downlink control information is detected, it is necessary to perform detection by using the DCI format that corresponds to A, C and D in the 2x expanded search space.
    In this case, the downlink control information that corresponds to all or part of the downlink component carriers that can be programmed by the downlink component carrier A is sent by the base station in the extended search space of the downlink component carrier. downlink A. MODALITY II
    If the EU DL component carrier set and the PDCCH monitoring set are uneven in size, the number h of carriers that can be programmed by each downlink component carrier that can perform cross carrier programming is purchased, where these carriers h include the carrier itself, and the search space of the downlink component carrier that can perform cross-carrier programming is expanded to search space H, where there is a one-to-one correspondence between the expanded search for the bearers of the downlink component h.
    The locations of the search space H are continuous, or the beginning of the locations of the search space H is produced according to the downlink component carrier index that corresponds to the search space.
    If H search spaces are produced according to the downlink component carrier index that corresponds to the search space, when performing DCI detection, user equipment needs to determine the start of search space carrier locations H according to the downlink component carrier index and then perform DCI detection.
    For example, M = 4, L = 1, P = 1, the downlink component carriers are A, B, C, and D respectively, where A can perform cross carrier programming. Assuming that, when A's search space is performing single carrier programming, the size of the search space is X. When cross-carrier programming is performed, A can program B, C, and D, and the A's search space is 4x, where the 3x extended search space is B, C and D's search space, and there is a one-to-one correspondence between the expanded search space and the carriers. For example, the search spaces are numbered 1 to 4x, where 1 ax is the search space for A, x + 1 to 2x is the search space for B, 2x + 1 to 3x is the search space for C, and 3x + 1 to 4x is the search space of D. When downlink control information is detected, in each search space with the size of it being x, the DCI format that corresponds to the search space is used for detection, for example, x + 1 to 2x is the search space of B, so the DCI format of b is only used for detection in that search space, compared to the use of all DCI formats for detection in each space in Mode I search, the number of DCI format detections is reduced.
    In this case, the downlink control information that corresponds to the downlink component carrier Y that can be programmed by the downlink component carrier A is sent by the base station through the search space that corresponds to the downlink component carrier. downlink Y extended by the downlink component carrier A, and the downlink component carrier Y is any one of the downlink component carriers h that can be programmed by the downlink component carrier A.
    When performing cross carrier programming in this scenario, the search space of the component carrier itself whose cross carrier programming is performed, can be used to perform blind detection of PDCCH, so it is more convenient to allocate the blind detection space and at the same time, the deployment complexity can be reduced.
    According to the detection method described above, the device for detecting downlink control information in the modalities of the present invention is applied to the user equipment, in which the device is configured to: during cross-carrier programming, determine a space search to monitor a physical downlink control channel (PDCCH) according to the number of downlink component carriers in a PDCCH monitoring set and the number of downlink component carriers in a carrier set EU DL component.
    The device can be configured to: if the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set are the same, adjust the search space to monitor the PDCCH to be consistent with that search space for single carrier programming; and if the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the EU DL component carrier set are uneven, expand the search space to monitor the control channel physical downlink (PDCCH) on carriers that can carry out cross carrier programming. In this case, the expanded search space is a specific user search space.
    The device can be configured to: expand equal search space for each bearer of downlink component that performs cross bearer programming in the PDCCH monitoring set.
    The expanded search space is determined by the increased number of monitoring times of the downlink component carrier that can perform cross-carrier programming, in which the expanded number of monitoring times is determined according to the difference between the number of downlink component carriers in the PDCCH monitoring set and the number of downlink component carriers in the UE DL component carrier set. The increased number of monitoring times is
    where M is the number of downlink component carriers in the EU DL component carrier set, Leo is the number of downlink component carriers in the PDCCH monitoring set, P is the number of downlink component carriers which can carry out cross carrier programming in the PDCCH monitoring set, and N is the maximum number of monitoring times for each downlink component carrier when cross carrier programming is not performed.
    The device can be configured to: allocate the search space that corresponds to the expanded number of monitoring times for each downlink component carrier, which can carry out cross carrier programming is deployed using the following method: select the levels aggregation H of aggregation levels 1, 2, 4 and 8 in the search space of the specific UE and add PDCCH A candidates in each selected aggregation level respectively,
    where H ^ {1,2,3,4}, B is the number of downlink control information formats (DCI format) under each transmission mode.
    The device can be configured to additionally: if the downlink component carrier A is able to perform cross carrier programming, detect the downlink control information that corresponds to all or part of the downlink component carriers that can be programmed by the downlink component carrier A in the extended search space of the downlink component carrier A. the downlink control information that corresponds to all or part of the downlink component carriers, which can be programmed by downlink component carrier A, are sent by the base station in the extended search space of the downlink component carrier A.
    The device can be configured to: if the downlink component carrier b is able to perform cross carrier programming and is able to program downlink component carriers h, increase the carrier's search space to the search space H, where there is a one-to-one correspondence between the expanded search space h and the downlink component carriers h.
    In this case, the locations of the search space H are continuous, or the locations of the search space H are produced according to the index of the downlink component carrier that corresponds to the search space.
    The device can be configured to additionally: detect downlink control information from the downlink component carrier that corresponds to the search space in the expanded search space.
    Downlink control information from the downlink component carrier Y is sent through a base station via the search space that corresponds to the downlink component carrier Y after the downlink component carrier b is increased , where the downlink component carrier Y is any one of the downlink component carriers h.
    Those skilled in the art should understand that all or part of the steps in the methods mentioned above can be completed using programs that instruct relevant hardware, and the programs can be stored on a readable medium storage computer, such as ROM memory, magnetic disk, or optical disc, etc. optionally, all or part of the stages of the modalities mentioned above can be additionally implemented through the use of one or more integrated circuits. As a consequence, the respective module / unit in the mentioned modalities can be implemented in the form of a hardware or software function module. The present invention is not limited to any particular form of combination of hardware and software.
    Although the present invention is described in conjunction with specific modalities, those skilled in the art can make modifications and changes without departing from the spirit or scope of the present invention. Such modifications and changes are considered to fall within the scope of the present invention and the scope of the appended claims. INDUSTRIAL APPLICABILITY
    The present invention provides a method and device for detecting downlink control information, in which the search space for monitoring PDCCH is determined according to the number of downlink component carriers in the PDCCH monitoring set and the EU carrier DL component set so that it performs blind detection on the PDCCH.
    权利要求:
    Claims (8)
    [0001]
    1. METHOD FOR DETECTING DOWNLINK CONTROL INFORMATION, characterized by understanding: during cross-carrier programming, according to the number of downlink component carriers in a physical downlink control channel, PDCCH, Monitoring Set and a the number of downlink component carriers in the user equipment, EU, DL being an uneven component carrier set and a downlink carrier component b of the cross carrier schedule there is a downlink carrier component, the UE determines that a search space of the downlink carrier component b comprises h in the search space in which there is a one-to-one correspondence between the search spaces h and the downlink component carriers h, and oh is an integer greater than 0; and the user equipment for detecting downlink control information from the downlink component carrier h that corresponds to the search space h in the search space.
    [0002]
    2. METHOD, according to claim 1, characterized in that the locations of the search spaces H are continuous, or the locations of the search spaces h are produced according to a downlink component carrier index that corresponds to the search space .
    [0003]
    3. METHOD, according to claim 1, characterized by understanding the downlink control information of the downlink component carrier Y is sent to the base station through the search space that corresponds to the downlink component carrier Y, where the downlink component carrier Y is any one of the downlink component carriers h.
    [0004]
    4. METHOD according to any one of claims 1 to 3, characterized in that search spaces h are a user-specific search space.
    [0005]
    5. DEVICE FOR DETECTING DOWNLINK CONTROL INFORMATION, applied to user equipment, characterized by during cross-carrier programming, according to the number of downlink component carriers in a downlink control channel, PDCCH, Monitoring Set and a number of downlink component carriers in the user equipment, EU, DL being an uneven component carrier set and a downlink carrier component b of the cross carrier programming h component of downlink bearer, the UE determines that a downlink bearer component search space b comprises h in the search space in which there is a one-to-one correspondence between the search spaces h and the link component bearers descendant h, eoh is an integer greater than 0; and the user equipment for detecting downlink control information from the downlink component carrier h that corresponds to the search space h in the search space.
    [0006]
    6. DEVICE, according to claim 5, characterized in that the locations of the search spaces h are continuous or the locations of the search spaces h are produced according to a downlink component carrier index that corresponds to the search space .
    [0007]
    7. DEVICE, according to claim 5, 5 characterized in that the downlink control information of the downlink component carrier Y is sent from a base station through the search space that corresponds to the downlink component carrier 10 Y , where the downlink component carrier Y is any one of the downlink component carriers h.
    [0008]
    8. DEVICE, according to any one of claims 5 to 7, characterized in that 15 search spaces h are a user-specific search space.
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    同族专利:
    公开号 | 公开日
    KR101447607B1|2014-10-06|
    US20120263052A1|2012-10-18|
    BR112012016267A2|2017-12-12|
    JP2013515406A|2013-05-02|
    EP2501173A4|2016-06-01|
    CN101790190A|2010-07-28|
    EP3454592B1|2020-10-14|
    ES2830049T3|2021-06-02|
    EP2501173B1|2018-12-19|
    EP3454592A1|2019-03-13|
    JP5634527B2|2014-12-03|
    CN101790190B|2014-12-10|
    KR20120115363A|2012-10-17|
    RU2528605C2|2014-09-20|
    RU2012127629A|2014-02-20|
    US8861500B2|2014-10-14|
    MX2012007969A|2012-08-03|
    EP2501173A1|2012-09-19|
    WO2010149106A1|2010-12-29|
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    法律状态:
    2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-12-17| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2019-12-24| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04W 24/10 Ipc: H04L 5/00 (1968.09), H04W 24/10 (2009.01), H04W 48 |
    2021-01-19| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-02-23| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 23/02/2021, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    CN201010002227.1|2010-01-08|
    CN201010002227.1A|CN101790190B|2010-01-08|2010-01-08|Method and device for detecting downlink control information|
    PCT/CN2010/074845|WO2010149106A1|2010-01-08|2010-06-30|Method and device for detecting downlink control infomation|
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