method for downlink control channel design

专利摘要:
the modalities of this disclosure improve the reliability of blind decoding when the beamforming is used with a user equipment (eu) receiving a single message from the downlink control information (dci) with different transmission and / or reception parameters. in some embodiments, an eu receives more than one set of configuration parameters, where any two sets of configuration parameters from more than one set of configuration parameters have at least one different parameter. the eu can receive two sets of configuration parameters each having different transmission modes, but the same type of search space. additional examples are also provided.
公开号:BR112019014030A2
申请号:R112019014030
申请日:2018-01-04
公开日:2020-02-04
发明作者:Maaref Amine；Gong Zhengwei
申请人:Huawei Tech Co Ltd；
IPC主号:

专利说明:

METHOD FOR DESIGNING DOWNLIGHT CONTROL CHANNEL [001] This patent application claims priority for US Provisional Patent Application 62 / 442,900 filed on January 5, 2017 and entitled Method for Downlink Control Channel Design and US Provisional Patent Application 62 / 455,485 filed on February 6, 2017 and entitled Method for Downlink Control Channel Design and Non-Interim Patent Application US 15 / 861,393 filed on January 3, 2018 and entitled Method for Downlink Control Channel Design. All patent applications mentioned above are incorporated into this document by reference as if reproduced in their entirety.
TECHNICAL FIELD [002] The present disclosure relates generally to telecommunications and, in specific modalities, to systems and methods for downlink control channel design, which may include Physical Downlink Radio Control Channel design Next (NR-PDCCH).
BACKGROUND [003] Wireless signals communicated at high carrier frequencies, such as millimeter wave (mmW) signals, tend to exhibit high loss of travel in free space. To compensate for the high rates of travel loss, high frequency communications can use beam formation on both the transmitter and the receiver. Beam blocking may occur when the transmit (TX) and / or receive (RX) beam directions being used for downlink transmission and reception by the base station and user equipment (UE) are not updated to
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2/44 compensate for the condition of the air interface and / or the relative positioning of the UE. A beam blocking condition can significantly impact performance when it prevents the UE from decoding downlink control information in a unit of time, since downlink control information may be required to locate and decode information from downstream data. downlink in the time unit.
BRIEF DESCRIPTION OF THE DRAWINGS [004] For a more complete understanding of the present disclosure, and its advantages, reference is now made to the following descriptions considered in conjunction with the accompanying drawings, in which:
Figure 1 is a diagram of a wireless communications network modality;
Figures 2A and 2B are diagrams of how a beam block condition can occur when beam formation is used to transmit or receive a Downlink Control Information (DCI) message;
Figures 3A and 3B are diagrams of modalities of DCI transmission and reception schemes that use transmission (TX) and reception (RX) beam directions;
Figure 4 is a diagram of a downlink time unit that carries multiple search spaces that are monitored by a UE in an attempt to decode a single DCI message;
Figure 5 is a diagram of another downlink time unit that carries multiple search spaces that are monitored by a UE in an attempt to decode a single DCI message;
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3/44 Figure 6 is a flowchart of a method modality for monitoring multiple research spaces;
Figure 7 is a flow chart of a method modality for configuring a UE to monitor multiple research spaces;
Figure 8 is a table that details exemplary parameters that can be configured for a downlink control channel;
Figure 9 is a block diagram that illustrates a relationship between types of survey spaces and one or more sets of control channel configurations associated with those;
Figure 10 is a group of examples that illustrates the relationship between type of research space, set of control resources and occurrences of transmission over the network;
Figure 11 is a block diagram illustrating associations for sets of control resources for a transmission resource for a given type of research space in a Time Division Multiplexing (TDM) modality and Frequency Division Multiplexing modalities (FDM);
Figure 12A is a flowchart that describes a method for configuring a UE with multiple configuration settings according to one embodiment of the disclosure;
Figure 12B is a flow chart describing another method for configuring a UE with multiple configuration settings according to a disclosure embodiment;
Figure 13 is a flowchart describing a method for configuring a UE to receive more than one occurrence of a DCI message according to one embodiment of the disclosure;
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4/44 Figure 14 is a flow chart of a method modality for monitoring research spaces;
Figure 15 is a flow chart of another method modality for monitoring research spaces;
Figure 16 is a block diagram of a processing system modality for carrying out the methods described in this document; and Figure 17 is a block diagram of a transceiver adapted to transmit and receive signaling over a telecommunications network in accordance with exemplary modalities described in this document.
SUMMARY [005] Technical advantages are generally achieved by the modalities of this disclosure, which describes techniques for a unifying message to support systems and methods for downlink control channel design.
[006] According to one modality, a method is provided to monitor research spaces. In this modality, the method includes receiving a first configuration signal from a base station, monitoring a first search space for one or more downlink control information (DCI) messages according to the first configuration parameters specified by the first signaling from configuration, and monitor a second search space for one or more DCI messages according to second configuration parameters different from the first configuration parameters. The second configuration parameters are predefined, specified by the first configuration signal, or specified by a second configuration signal received by the UE
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5/44 from the base station. In one example, the second configuration parameters are predefined based on the synchronization channel by which a synchronization signal is received by the UE from the base station. In that example, or in another example, the second configuration parameters are predefined based on the second configuration signal received by the UE from the base station. In either of the preceding examples, or in another example, the first configuration parameters and the second configuration parameters individually comprise a reference signal structure (RS), a type of search space, one or more levels of aggregation, a candidate number, a set of control features, a coupling between different parameters associated with the first or second configuration parameters, or a combination of these. In such an example, the first configuration parameters may differ from the second configuration parameters with at least one of: the reference signal structure (RS), the type of search space, the one or more levels of aggregation, the candidate number and the set of control features. Additionally or alternatively, the RS structure may specify a random sequence initialization number, the first configuration signal may specify a first random sequence initialization number, the second configuration signal may specify a second random sequence initialization number, and the method may further include monitoring the first search space using the first random sequence initialization number, and monitoring the second search space using the second random initialization number of
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6/44 sequence. In either of the preceding examples, or in another example, the first configuration signal specifies a first random sequence initialization number, the set of predefined configuration parameters specifies a second random sequence initialization number, and the method may include monitoring the first search space using the first random sequence initialization number, and monitoring the second search space using the second random sequence initialization number.
[007] In either of the preceding examples, or in another example, the first configuration signal is radio resource control (RRC) signal or broadcast signal. In either of the preceding examples, or in another example, the first configuration signal is RRC signal and the second configuration parameters are specified by the RRC signal. In either of the preceding examples, or in another example, the first configuration signal is broadcast signal and the second configuration parameters are specified by the broadcast signal. In either of the preceding examples, or in another example, the second configuration signal is RRC signal. In either of the preceding examples, or in another example, the first configuration signal and the second configuration signal include the same RRC signal. In any of the preceding examples, or in another example, any of the first research space or the second research space is a common research space, an EU-specific research space, or a specific research space of
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7/44 group. In either of the preceding examples, or in another example, the second search space is a different type of search space than the first search space. In either of the preceding examples, or in another example, the first research space is a common research space or a group-specific research space and the second research space is an EU-specific research space or a research space group specific. In either of the preceding examples, or in another example, monitoring the first search space for one or more DCI messages comprises monitoring the first search space for a first occurrence of a first DCI message, and monitoring the second search space for one or more DCI messages it comprises monitoring the second search space for a second occurrence of the first DCI message. In either of the preceding examples, or in another example, monitoring the first search space for one or more DCI messages comprises monitoring the first search space for a first occurrence of a first DCI message, and monitoring the second search space for one or more DCI messages it comprises monitoring the second search space for a first occurrence of a second DCI message, where the first DCI message and the second DCI message are associated with the same RNTI or UE ID. An apparatus is also provided to perform this method.
[008] According to another modality, a method is provided to configure research spaces. In this modality, the method includes transmitting a first configuration signal to a user equipment (UE) that instructs the
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UE to monitor a first research space according to the first configuration parameters. The UE is configured to monitor a second search space according to second configuration parameters that are predefined, specified by the first configuration signal, or specified by a second configuration signal received by the UE from the base station. An apparatus is also provided to perform this method.
[009] According to yet another modality, another method is provided to monitor research spaces. In this mode, the method includes monitoring multiple search spaces for a downlink control (DCI) information message using different UE reception beams. In one example, multiple search spaces comprise at least two of a common search space, an EU-specific search space and an EU group-specific search space, where the common search space is configured with predefined information or control signaling transmitted by a broadcast channel, the UE specific search space is configured with UE specific control signaling transmitted by a point-to-point transmission channel, and the UE group specific search space is configured with specific group information and specific EU control signaling transmitted over a point-to-point transmission channel. In the same example, or in another example, the multiple research spaces being monitored by the UE include at least two research spaces that have different modes of transmission. In any of the preceding examples, or in another example, the multiple research spaces being monitored by the UE
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9/44 include at least two research spaces that have different reference signal configurations. In either of the preceding examples, or in another example, the multiple research spaces being monitored by the UE include two research spaces transmitted by different carrier frequencies or cells. In either of the preceding examples, or in another example, the multiple research spaces being monitored by the UE include research spaces transmitted according to different levels of aggregation. In either of the preceding examples, or in another example, the multiple research spaces being monitored by the UE include research spaces that have different modes of indication. In either of the preceding examples, or in another example, different occurrences of the DCI message are transmitted in two or more different research spaces being monitored by the UE. In either of the preceding examples, or in another example, the UE monitors multiple search spaces after receiving a configuration signal that instructs the UE to monitor multiple search spaces. An apparatus is also provided to perform this method.
DETAILED DESCRIPTION OF ILLUSTRATIVE MODALITIES [0010] The structure, manufacture and use of modalities provided in this document are discussed in detail below. It should be understood, however, that the present disclosure provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific modalities discussed are merely illustrative of specific ways of making and using the disclosure, and do not limit the scope of the disclosure. THE
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10/44 The term beam direction refers to a radio antenna pattern, or set of beam-forming weights, which is used for directional signal transmission and / or reception. The terms beam and beam directions are used interchangeably in this document.
[0011] Downlink control (DCI) information messages are typically decoded by the UE through a process referred to as blind decoding. Blind decoding reduces network overhead by allowing UEs to detect which set of control channel elements (CCEs) on a downlink control physical channel (PDCCH) carries a DCI message to the UE without having to transmit explicit signaling of control. In general, a UE performs blind decoding in a downlink control physical channel (PDCCH) search space when attempting to decode different candidate sets of control channel elements (CCEs) until one of the decryption attempts is successful. For example, an UE may first attempt to blindly decode the first CCE in a search space. If that decryption attempt is unsuccessful, then the UE can attempt to decode the first two CCEs in the search space, then the first four CCEs in the search space, and so on until a decryption attempt is successful. The UE attempts to blindly decode a specific candidate set of CCEs using the UE identifier on the network, for example, a temporary radio network identifier (RNTI), to unmask a cyclical redundancy check (CRC) of the candidate set of CCEs. If no error is detected
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CRC, so the decryption attempt was successful, and the UE processes the set of CCEs to decode a DCI message. In some modalities, blind decoding is performed in a first type of research space from multiple types of research spaces being monitored by the UE. The UE can be configured to decode a single DCI, multiple occurrences of a single DCI, multiple DCs or multiple occurrences of multiple DCI. The UE may not attempt to blindly decode remaining types of search spaces if the UE successfully decodes the DCI message, or messages, when performing blind decoding on the first type of search space.
[0012] When beamforming is used, blind detection can become less reliable because a beam block condition can prevent a UE from successfully decoding a DCI message in the search space. This can significantly degrade performance because the failure of the UE to correctly decode a DCI message in a time unit's control channel can likely prevent the UE from finding, and decoding, data in a time unit's data channel. mode potentially requiring retransmission of data in a subsequent unit of time.
[0013] Modalities of this disclosure improve blind decoding reliability when beamforming is used when the UE receives a single downlink control information (DCI) message with different transmission and / or reception parameters. The term transmission and / or reception parameters refers to one or more parameters used for Physical Control Channel
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Near Radio Downlink (NR-PDCCH) to transmit and / or receive a DCI message, such as, but not limited to, a transmission mode used to transmit the DCI message, a reference signal (RS) structure used for channel estimation for the DCI message; a receiving beam related to a beam pair link that can be switched to receive the DCI message; a type of research space to be monitored to receive the DCI message, a candidate number and an aggregation level to define the research space; a set of control features used to map the DCI message and a configuration set index used to identify, but not limited to, configured parameters. The relationship between different parameters of a set of parameters configured for NR-PDCCH can be considered as an association or a coupling. For example, a relationship between the type of search space and a control resource (resource designation T-F) is configured within a control channel configuration.
[0014] The transmission mode can be a diversity mode, such as diversity pre-coding (for example, frequency block space coding, SFBC and pre-coding switching / cycling) or spatial multiplexing.
[0015] The reference signal structure (RS) can comprise at least one parameter outside the signaling method, random sequence initialization number, time / frequency resource and number and / or antenna port index in which the method signaling could be defined, broadcast channel or dedicated channel; the random number of
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13/44 sequence initialization can be cell ID or some other configured ID; the time / frequency resource can be an OFDM symbol index and / or a subcarrier carrier index; and the antenna port number and / or index can be the antenna port number and / or index.
[0016] The receiving beam may comprise at least one parameter such as the receiving beam index and / or time unit associated with the specific beam index. The time unit comprises one of an OFDM symbol, a group of OFDM symbols, a mini-slot, a slot and a subframe. For multiple occurrences of messages from a single DCI and / or messages from multiple DCI, the receive beam for each occurrence includes a receive beam index and a time unit for the respective receive beam index.
[0017] The type of research space could be one of Common Research Space (CSS) or EU Group Research Space (UGSS) which is for reception by multiple UEs or specific EU Research Space (USS) which is specific for a single EU. A common research space can be either a pre-configured research space or a research space configured by means of control signaling transmitted by a broadcast channel, EU-specific and group-specific research spaces can be configured via EU-specific and group-specific control signals (respectively) transmitted over a point-to-point transmission channel.
[0018] The designation of a set of time / frequency resources (that is, a set of control resources) is defined as a set of Groups of
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Resources (REGs) according to a specific numerology. In some implementations a REG is four consecutive Resource Elements (RE). An RE is a minor element of the transmission resource, which can, for example, be 1 symbol per 1 subcarrier.
[0019] A common search space for a type of search space can be defined by at least some of the following properties: one or more levels of aggregation, a number of coding candidates for each level of aggregation and a set of Elements of Control Channel (CCEs) for each decoding candidate. A candidate is a location in the search space that can include downlink control information for the UE. In some implementations, a CCE can be nine REGs
consecutive. An Aggregation can be 1, 2, 4 or 8 CCEs consecutive. As example, a level of aggregation in 2 would be 2 consecutive CCEs. [0020] In some modalities, a UE receives more of
a set of configuration parameters, where any two sets of configuration parameters outside of more than one set of configuration parameters have at least one different parameter. In a first example, the UE receives two sets of configuration parameters having individually different transmission modes, but the same type of search space. In a second example, the UE receives two sets of configuration parameters that individually have a different type of search space, but the same transmission mode. In a third example, the UE receives two sets of configuration parameters that individually have a different type of search space, but
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15/44 the same set of control features. In a fourth example, the UE receives two sets of configuration parameters that individually have a different set of control features, but the same type of search space. In a fifth example, the UE receives two sets of configuration parameters that individually have a different reception beam, but the same type of search space. In some embodiments, the UE receives more than one set of configuration parameters in which at least one of the parameters of any set of more than one set of configuration parameters can be configured by default of at least one parameter, transmission of at least one parameter with a broadcast and transmission channel of at least one parameter with a dedicated channel. Once the UE is configured with multiple control channel configuration sets, the network can transmit downlink control channel configuration information in a mode that is consistent with one or more of the configurations. The UE may attempt to blindly decode the control information as described above based on the various configurations with which it is configured.
[0021] In some embodiments, the UE receives a DCI message using more than one transmission mode, which could be diversity pre-coding (eg space frequency block coding (SFBC) or pre-switching / cycling) -coding) or spatial multiplexing. In one example, an instance of a DCI message can be transmitted with only one or more of a transmission mode (e.g., SFBC) while the UE will use more than one transmission mode to receive a DCI message. In
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16/44 another example, more than one occurrence of a DCI message can be transmitted each with a different mode of transmission (for example, SFBC and spatial multiplexing) while the UE will use more than one mode of transmission to receive at least one occurrence of a DCI message. For these modalities, the UE can be configured to monitor multiple types of research spaces that are associated with different modes of transmission to receive a DCI message.
[0022] Modalities of this disclosure improve blind decoding reliability when beamforming is used when the UE monitors multiple search spaces for a single downlink control information (DCI) message. The multiple research spaces being monitored by the UE can be orthogonal in the time domain and / or in the frequency domain. In some modalities, the multiple research spaces monitored include different types of research spaces. In one example, the multiple research spaces monitored include at least two from a common research space, an EU-specific research space and a group-specific research space.
[0023] In some embodiments, the UE receives a DCI message using more than one RS structure with different parameters including at least one of the signaling method, random sequence initialization number, time / frequency resource and port number of antenna and / or antenna port index. The signaling method can be predefined, transmitted over a broadcast channel or transmitted over a dedicated channel. For a first example, an instance of a DCI message can be transmitted
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17/44 with only one RS structure that is indicated with a broadcast channel while the UE will use more than one RS structure with different signaling methods (broadcast channel or dedicated channel) to receive a DCI message. For a second example, an instance of a DCI message can be transmitted with only one RS structure with a cell ID as a random sequence initialization number while the UE will use more than one RS structure with different random initialization numbers (cell ID and other configured ID) to receive a DCI message. For a third example, a UE can monitor a first DCI lookup space for message (s) according to a random sequence initialization number specified by broadcast signaling, and monitor a second DCI lookup space for message (s) according to random sequence initialization number specified by RRC signaling. For a fourth example, a UE can monitor a first lookup space for DCI message (s) according to a predefined (or pre-associated) sequence initialization number with a cell identifier (ID) corresponding to the synchronization channel whereby the synchronization signal was received from the base station, as well as monitoring a second polling space for at least one DCI message according to the random sequence initialization number specified by the RRC signaling. In any of these modalities, the second research space can be a different type of research space than the first research space. For example, the first research space can be a common research space and the second research space
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18/44 research can be an EU-specific research space. The broadcast signaling can be system information block (SIB) signaling.
[0024] In some modalities, the UE uses different reception beam (RX) directions to sample different types of research spaces. In some embodiments, the UE uses different reception beam (RX) directions to sample multiple different sets of control resources associated with the same type of research space. In some embodiments, the UE can use multiple RX beam directions to sample a set of control features. For example, a set of control features comprises multiple time units that could be at least one of an OFDM symbol, a group of OFDM symbols, a mini-slot, a slot and a subframe. According to the time unit index and receive beam index configured for this time unit, the UE switches the receive beam to receive a DCI message.
[0025] In some modalities, the UE can receive multiple repeated occurrences of a DCI message in which multiple occurrences can be mapped through multiple types of research spaces and / or sets of control resources. In one example, multiple occurrences can be mapped across multiple types of search spaces while each type of space is associated with a specific set of control resources. In another example, multiple occurrences can be mapped through multiple sets of control resources associated with a type of research space. In another example, multiple occurrences can be mapped across multiple
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19/44 sets of control resources associated with more than one type of research space. The number of repeated occurrences can be explicitly indicated or implicitly indicated, for example, as a number of different types of survey spaces that are configured to be monitored or as a number of all sets of control features configured to be monitored. In all embodiments, multiple decoded DCI messages can be combined for robust decoding to a DCI message where each occurrence can be independently decoded to a DCI message.
[0026] In some embodiments, the UE can receive more than one DCI message with the same UE or RNTI ID in which more than one DCI message can be received with different transmission and / or reception parameters including at least one of transmission mode, reference signal structure (RS), reception beam, type of research space and set of control features.
[0027] In one embodiment, a UE can monitor a first DCI message search space (s) according to configuration parameters specified by broadcast signaling, and monitor a second DCI message search space (s) from according to configuration parameters specified by RRC signaling. In another embodiment, the UE can monitor a first search space for DCI message (s) according to configuration parameters pre-associated with a cell identifier (ID) corresponding to the synchronization channel through which the synchronization signal was received base station, as well as monitoring a second research space for at least
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20/44 a DCI message according to configuration parameters specified by the RRC signaling. In any of these modalities, the second research space can be a different type of research space than the first research space. For example, the first research space can be a common research space and the second research space can be an EU-specific research space. The broadcast signaling can be system information block (SIB) signaling.
[0028] Downlink control (DCI) information messages are typically decoded by the UE through a process referred to as blind decoding. Blind decoding reduces network overhead by allowing UEs to detect which set of control channel elements (CCEs) on a physical downlink control channel (PDCCH) carries a DCI message to the UE without having to transmit explicit signaling from control. In general, a UE performs blind decoding in a search space of a downlink control physical channel (PDCCH) when attempting to decode different candidate sets of control channel elements (CCEs) until one of the decoding attempts is successful. For example, an UE may first attempt to blindly decode the first CCE in a search space. If that decryption attempt is unsuccessful, then the UE can attempt to decode the first two CCEs in the search space, then the first four CCEs in the search space, and so on until a decryption attempt is successful. The UE tries to blindly decode a specific candidate set of CCEs using the
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21/44 UE identifier in the network, for example, a temporary radio network identifier (RNTI), to unmask a cyclical redundancy check (CRC) of the candidate set of CCEs. If no CRC error is detected, then the decryption attempt was successful, and the UE processes the set of CCEs to decode a DCI message.
[0029] When beamforming is used, blind detection can become less reliable because a beam-blocking condition can prevent a UE from successfully decoding a DCI message in the search space. This can significantly degrade performance because the failure of the UE to correctly decode a DCI message in a time unit's control channel can likely prevent the UE from finding, and decoding, data in a time unit's data channel. mode potentially requiring retransmission of data in a subsequent unit of time.
[0030] Modalities of this disclosure improve blind decoding reliability when beamforming is used by having the UE monitoring multiple search spaces for a single downlink control information (DCI) message. Research spaces can have different resource configurations to provide frequency and / or spatial diversity, thereby improving the likelihood that the DCI message will be successfully decoded. The term resource configuration refers to one or more parameters used to configure a research space, such as (for example) time / frequency resources (for example, physical resource blocks (PRBs)) mapped to the research space , carrier of
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22/44 frequency used to transmit the research space, a cell associated with the research space, an antenna port associated with the research space, a beam direction used to transmit or sample the research space, a transmission mode associated with the search space, a number of reference signs in the search space, the location of reference signs in the search space and CCE aggregation levels associated with the search space. In one modality, a single occurrence of a DCI message is transmitted in one of the monitored research spaces. In another embodiment, multiple occurrences of a DCI message are transmitted in different research spaces to provide the UE with multiple opportunities to decode the DCI message. In both modalities, the UE can sample all the research spaces being monitored by the UE, and then blindly decode one of the sampled research spaces in an attempt to decode the DCI message. If the UE is able to decode the DCI message, then the UE can use the DCI message to decode a corresponding data transmission using the DCI message without blindly decoding any of the other search spaces. Alternatively, if the UE is unable to successfully decode the DCI message when blindly decoding the first search space, then the UE can blindly decode another of the sampled research spaces. This can continue until the UE or decode the DCI message, or fail to decode a DCI message after blindly decoding all sampled search spaces.
[0031] In some modalities, the UE uses different
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23/44 receiving beam directions (RX) to sample different research spaces. In some modalities, multiple beams can be used to sample the same research space. The UE can select the RX beam direction to use for a given search space based on a resource configuration associated with the search space. In some embodiments, the base station transmits different occurrences of a given DCI message using different TX beam directions to reduce the likelihood of beam blocking on the transmitter side.
[0032] In some modalities, research spaces with different resource configurations can be used to transmit different occurrences of the same DCI message. In one example, a search space configured with space frequency block encoding (SFBC) can be used to transmit an instance of a DCI message and a search space configured with a spatial multiplexing can be used to transmit another occurrence of the DCI message. The occurrences of the DCI message can be transmitted by both spaces simultaneously. Alternatively, the DCI message can be retransmitted by the SFBC-configured search space when a previous transmission of the DCI message by the configured space with spatial multiplexing has been successful, or vice versa. In another example, search spaces with different beam configurations (pairs) can be used to transmit occurrences of the same DCI message. The transmission of the DCI message through the research spaces with different beam configurations (pair) must be based on TDM (time division multiplexing). Alternatively,
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24/44 the DCI message can be retransmitted by one of the search spaces configured by bundles (even) when an initial transmission by the other research space configured by bundles (even) has been successful.
[0033] The multiple research spaces being monitored by the UE can be orthogonal in the time domain and / or in the frequency domain. In some modalities, the multiple research spaces monitored include different types of research spaces. In one example, the multiple research spaces monitored include at least one common research space, an EU-specific research space and a group-specific research space. A common research space can be either a pre-configured research space or a research space configured by means of control signaling transmitted by a broadcast channel, EU-specific and group-specific research spaces can be configured by means of signaling from EU-specific and group-specific control (respectively) transmitted over a point-to-point transmission channel.
[0034] As mentioned above, the multiple research spaces monitored may have different resource configurations. In one example, research spaces have different modes of transmission. In another example, search spaces can contain different reference signal configurations. For example, search spaces can include different types of reference signals (for example, cell reference specific signal (CRS), demodulation reference signal (DMRS), etc.), different numbers of reference signals, and / or transport
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25/44 the reference signals by different resources (for example, different time, frequency and antenna ports, etc.). In yet another example, one of the research spaces can use mapping of localized resources (for example, CCEs cover consecutive time / frequency resources), and the other research space can use mapping of distributed resources (for example, CCEs cover non-resource resources) consecutive time / frequency based on a skip / interleaving pattern). In yet another example, search spaces can be preconfigured and / or configured using different control signaling indications, for example, cell-specific control signaling, radio-specific channel resource control (RRC) signaling EU, etc. In yet another example, the research spaces can be transmitted by different carrier frequencies. In such an example, one search space can be transmitted over a high carrier frequency (for example, millimeter wave carrier frequency) and the other search space can be transmitted over a low carrier frequency (for example, between 1, 4 and 20 MegaHertz (MHz), etc.). In yet another example, research spaces can be transmitted through different physical channels of control. For example, one search space can be transmitted over a physical downlink control channel (PDCCH), and another search space can be transmitted over an enhanced PDCCH (ePDCCH). In yet another example, research spaces can be transmitted according to different levels of CCE aggregation. For example, an UE may try to blindly decode a search space using, for example, CCE aggregation level
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26/44 one and two, and then try to blindly decode another search space using CCE aggregation level four. Other examples are possible. For example, the UE may try to blindly decode a search space using each level of CCE aggregation in a set of levels of CCE aggregation (for example, levels of CCE aggregation one, two, four and eight), and then try to blindly decode other research spaces using a subset of CCE aggregation levels (for example, CCE aggregation levels four and eight). These and other aspects are discussed in more detail below.
[0035] In some modalities, research spaces being monitored by a UE have different modes of transmission. For example, research spaces being monitored by an UE may have different antenna port configurations. As another example, research spaces being monitored by a UE may have different layer mappings in relation to spatial multiplexing such that different numbers of space-time streams are used to transmit a DCI message in the respective research spaces. As another example, research spaces being monitored by a UE may have different layer mappings in relation to transmission diversity such that different numbers of antennas are used to transmit a given symbol in the respective research spaces.
[0036] Figure 1 is a diagram of a network 100 for communicating data. Network 100 comprises a base station 110 that has a coverage area 101, a plurality of user equipment (UEs) 120, and a backhaul network 130. As shown, base station 110 establishes connections
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27/44 uplink (dashed line) and / or downlink (dotted line) with UEs 120, which serve to carry data from UEs 120 to base station 110 and vice versa. Data carried over uplink / downlink connections can include data communicated between UEs 120, as well as data communicated to / from a remote end (not shown) via backhaul network 130. As used in this document, the term base station refers to any component (or set of components) configured (s) to provide wireless access to a network, such as an enhanced Node B (eNB), a transmit / receive point (TRP), a macrocell, a femtocell , a Wi-Fi access point (AP), and other wireless enabled devices. Base stations can provide wireless access in accordance with one or more wireless communication protocols, for example, new radio 5th generation (5G_NR), long-term evolution (LTE), advanced LTE (LTEA), Access Package High Speed (HSPA), Wi-Fi 802. lla / b / g / n / ac, etc. As used in this document, the term UE refers to any component (or set of components) capable of establishing a wireless connection with a base station, such as a mobile device, a mobile station (STA), or others wireless devices available. In some embodiments, the network 100 can comprise several other wireless devices, such as relays, low power nodes, etc.
[0037] When beamforming is used to transmit and / or receive a DCI message, DCI detection may become less reliable due to the potential for beam blocking. Figures 2A and 2B are diagrams of
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28/44 DCI transmission and / or reception schemes 201, 202 showing how a beam block condition can occur when a DCI message is transmitted from a base station 210 to a UE 220.
[0038] In Figure 2A, base station 210 selects a beam direction 213 by means of a beam scan or beam tracking procedure when the UE 220 is positioned in an initial location, and then transmits a DCI 233 message based on beam direction 213. The UE 220 migrates from the initial location to a subsequent location prior to the transmission of the DCI 233 message. The received signal / quality level of the DCI message 233 at the subsequent location is not sufficient to allow the UE 220 blindly decode the DCI message 233, thereby resulting in a beam block condition.
[0039] In Figure 2B, the UE 220 selects a beam direction 223 by means of a beam scan or beam tracking procedure when the UE 220 is positioned in an initial location. The UE 220 migrates from the initial location to a subsequent location prior to the transmission of a DCI message 241 by base station 210. The spatial performance of beam direction 223 is not sufficient to allow the UE 220 to blindly decode the DCI message 241, which causes a beam blocking condition.
[0040] Modalities of this disclosure improve the reliability of blind decoding by transmitting multiple occurrences of a DCI message in different types of research spaces in a unit of time. At
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29/44
Figures 3A and 3B are diagrams of modalities of DCI transmission schemes 301, 302 that mitigate beam block by transmitting multiple occurrences of a DCI message in different research spaces of a unit of time.
[0041] In Figure 3A, a base station 310 selects a beam direction 313 by means of a beam scan or beam tracking procedure when the UE 320 is at an initial location, and then transmits an occurrence of a message. DCI 333 by beam direction 313 and another occurrence of DCI 335 message by beam direction 315. UE 320 migrates from the initial location to a subsequent location prior to transmission of the occurrence of DCI 333, 335. In this example, the beam direction 315 has an alignment that is offset from beam direction alignment 333. As a result, the occurrence of the DCI message 335 transmitted by beam direction 315 has a better received signal strength or quality level than the occurrence of the message of DCI 333 transmitted by beam direction 313, and the UE 320 is able to blindly decode the occurrence of the DCI 335 message.
[0042] In Figure 3B, the UE 320 selects a beam direction 323 by means of a beam scan or beam tracking procedure when the UE 320 is positioned in an initial location. The UE 320 then migrates from the initial location to a subsequent location. Then, the base station 310 transmits two occurrences of a DCI message 343, 345 in different polling spaces of a unit of time. The occurrences of the DCI message 343, 345 can be omnidirectional transmissions.
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30/44
Alternatively, occurrences of the DCI message 343, 345 may be transmissions formed from a beam that are transmitted in the same beam direction, or in different directions of the beam. In this example, the UE 320 attempts to blindly decode the search space that carries the DCI message 343 using beam direction 323. The spatial performance of beam direction 323 at the subsequent location is not sufficient to allow the UE 320 to blindly decode the DCI message 343. The UE 320 then blindly decodes the search space that carries the DCI 345 message using beam direction 325. The spatial performance of beam direction 325 is sufficient to allow the UE 320 to blindly decode the message of DCI 345.
[0043] Although only two occurrences of the DCI message are represented as being transmitted in the form of DCI transmission schemes 301, 302, it should be understood that other modalities of DCI transmission schemes can transmit three or more occurrences of a DCI message DCI in different research spaces of a unit of time.
[0044] Research spaces being monitored by a UE can be multiplexed in the frequency domain. Figure 4 is a diagram of a downlink time unit 400 that carries multiple search spaces 410, 420 that are monitored by a UE in an attempt to decode a single DCI message. In this example, search spaces 410, 420 are multiplexed by frequency division. In some modalities, a single occurrence of a DCI message can be transmitted in one of the research spaces 410, 420. In another modality, an occurrence of
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31/44 a DCI message is transmitted in search spaces 410, and another occurrence of the DCI message is transmitted in search space 420.
[0045] Research spaces being monitored by a UE can also be multiplexed in the time domain. Figure 5 is a diagram of a downlink time unit 500 that carries multiple search spaces 510, 520 that are monitored by a UE in an attempt to decode a single DCI message. In this example, search spaces 510, 520 are multiplexed by time division. A single occurrence of a DCI message can be transmitted in one of search spaces 510, 520. Alternatively, different occurrences of a DCI message can be transmitted in search spaces 510, 520. Search spaces 510, 520 can have different resource configurations and / or can be received using different RX beam directions.
[0046] Figure 6 is a flow chart of a 600 method modality for monitoring multiple search spaces for a single DCI message, as can be performed by a UE. In step 610, the UE samples multiple research spaces. In step 620, the UE blindly decodes a first of the sampled research spaces. In step 630, the UE determines whether a DCI message has been decoded. If not, the UE determines whether any additional search spaces are left to blindly decode in step 640 and, if so, blindly decodes the next sampled search space in step 640 before returning to step 630. If the UE blindly decodes all the survey spaces sampled without decoding the DCI message, then
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32/44 the UE sends an error message to the base station in step 660. If the UE decodes the DCI message in one of the sampled search spaces, then the UE decodes data based on the DCI message in step 670.
[0047] Figure 7 is a flow chart of a 700 method modality for configuring a UE to monitor multiple search spaces for a DCI message, as it could be performed by a base station. In step 710, the base station sends a signal to a UE that indicates multiple configurations of search spaces. The signal can warn the UE to monitor multiple search spaces for a single DCI message. In step 720, the base station transmits one or more occurrences of a DCI message across one or more of the multiple search spaces being monitored by the UE. In step 730, the base station transmits data based on the DCI message.
[0048] Figure 8 is a table that illustrates an example of types of parameters that may be involved in the definition of a physical downlink control channel that the UE would need to configure to receive the information transmitted by the downlink control channel. The parameters shown in Figure 8 are merely examples of possible parameters. In other implementations, a selection subset of the parameters shown in Figure 8 can become the set of parameter settings, or a group of any of these parameters and other additional parameters can become the set.
[0049] Figure 9 illustrates an example of how a type of search space, for example, a USS or a CSS, can
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33/44 have one or more different sets of control channel settings parameters and how the sets of control channel settings can be associated.
[0050] A first type of search spaces 920 is associated with a single set of configuration parameters for control channel 925. A second type of search spaces 930 is associated with two sets of configuration parameters for control channel 935 and 937. The two different types of research spaces 920 and 930 are indicated to be associated with each other. The association of types of search spaces can essentially act as an index to simply define a combination of which types of search spaces are being used when more than one type of search space is being used by a UE.
[0051] A list of configuration parameters 940 is also known as types of example parameters that are found in configuration set 935. List 940, which points in particular to set 935, is intended to be merely an example of the parameters that are in any given set of parameters, and it is not intended to be just that set of parameters.
[0052] The parameters in list 940 are generally consistent with what is shown in Figure 8. List 940 includes an association of search space types 932, a configuration set index 944, a type of transmission (for example, localized or distributed) 946, a TF resource set designation (a control resource set) 948, a transmission mode (for example, spatial multiplexing diversity) 950, a
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34/44 RS structure (sequence random number and / or antenna port number) 952, a receive beam (for example, a beam index and its time unit) 954 and a multiplexing flag of Control channel (for example, a single bit that defines whether or not multiplexing exists) 956.
[0053] There may be additional parameters to those of Figure 8, or parameters not found in Figure 8, since these parameters are merely examples of possible parameters. In other implementations, a selection subset of the parameters shown in list 940 can become a set of parameter settings, or a group of any of these parameters and other additional parameters can become a set of parameter settings.
[0054] When receiving a control message, whether the message is repeated or not, the search space (s) associated with the same set of control resources may be different , at least in relation to a candidate number and aggregation level. This means that for a case where repetition is used, it may not be necessary to use low level aggregation transmission.
[0055] Within a set of control resources, at least one occurrence can be transmitted.
[0056] Table 1 below shows an example of the number of downlink control channel candidates that are used for transmission without repetition for two different sets of parameter settings (set 1 and set 2) for four different levels of
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35/44 aggregation, L = 1, L = 2, L = 4 and L = 8. The pair of numbers for each level of aggregation represents the number of candidates that could be used to transmit occurrences for each respective set of parameters.
Table 1
Number of NR-PDCCH candidates without repetition L = 1 L = 2 L = 4 L = 8Set 1 Set 2 1, 1 1, 1 4, 4 2.2
[0057] Table 2 below shows an example of the number of downlink control channel candidates that are used for repetition transmission for two different sets of parameter settings (set 1 and set 2) for four different levels of aggregation, L = 1, L = 2, L = 4 and L = 8. The pair of numbers for each aggregation level represents the number of candidates that could be used to transmit occurrences for each respective set of parameters.
Table 2
Number of NR-PDCCH candidates with repetition L = 1 L = 2 L = 4 L = 8Set 1 Set 2 0, 0 0, 0 4, 4 2.2
[0058] Figure 10 illustrates six examples of configurations for transmission to a UE over the network based on the variables of the type of search space, set of control resources for each type and number of transmission occurrences. Each of the six examples illustrates a transmission resource in which the type of resource space increases in a vertical direction and a set of control resources increases in a horizontal direction. In (a) there is a single type of research space being used (from a group of
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36/44 possible types of research spaces) that have a single set of control features for transmitting a single occurrence. In (b) there are two types of research spaces that have a single set of control resources for transmitting the same single occurrence. In (c) there are two types of research spaces each having a single set of control resources for transmitting a respective single occurrence, that is, two occurrences in total. In (d) there is a single type of research space that has two sets of control resources for transmitting a single occurrence. In (e) there is a single type of research space that has two sets of control resources, each for transmitting a respective single occurrence, that is, two occurrences in total. In (f) there are two types of research spaces, a first type of research space having a set of control resources for transmitting a single occurrence and a second type of research space having two sets of control resources, each for transmission of a respective occurrence, that is, three occurrences in total.
[0059] Figure 11 illustrates examples of three sets of control resources in (a) a time division multiplexing (TDM) format associated with a type of research space and three sets of control resources in (b) one frequency division multiplexing (FDM) format associated with a type of research space.
[00 60] Figure 12A is a flow chart illustrating a method 1200 for configuring a UE from the perspective of the UE. The method involves in step 1210 providing the UE with a plurality of configuration settings to receive a
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37/44 downlink control (DCI) information message for a downlink control physical channel. Each configuration definition defines at least one parameter, where at least one parameter in each configuration definition includes at least one of: a transmission mode; at least one reference signal (RS) structure; at least one receiving beam related to a specific beam pair link; a type of research space; a level of aggregation; a candidate number; a time / frequency resource pool designation; and an index of configuration sets. In step 1220, the UE is configured with the plurality of sets of configuration settings. One or more of the configuration settings (for example, type of search space, aggregation level, candidate number, etc.) can be identified by means of explicit signaling, for example, RRC signaling, etc. Step 1230 involves monitoring, by the UE using the plurality of configuration settings, at least one type of search space for a specific DCI message, where each of the at least one type of search space is associated with respective parameters of transmission and / or reception that correspond to at least one of the configuration settings.
[00 61] Figure 12B is a flow chart illustrating a method 1250 for configuring a UE from the perspective of the base station. Step 1260 includes transmitting, through the base station, a plurality of configuration settings for receiving DCI messages to a physical downlink control channel. Each configuration definition defines at least one parameter, where the at least one parameter in each configuration definition includes at least one of: a
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38/44 transmission; at least one reference signal (RS) structure; at least one reception beam index related to a beam pair link; a type of research space; a level of aggregation; a candidate number; a time / frequency resource pool designation; and an index of configuration sets. Step 1270 includes transmitting a DCI message via a downlink control physical channel through the base station, wherein the DCI message has respective transmission and / or reception parameters that correspond to at least one of the configuration settings that allows the DCI message to be decoded.
[00 62] Figure 13 is a flow chart illustrating a 1300 method for configuring a UE from the perspective of the base station. Step 1310 includes transmitting, via the base station, more than one occurrence of a DCI downlink control information message, wherein each occurrence of more than one occurrence of the DCI message has a respective resource configuration. Step 1320 involves transmitting, through the base station, a number of more than one occurrence of the DCI message in the form of at least one of: a number of different types of research spaces configured to be monitored; and a number of all control feature sets configured to be monitored.
[0063] Figure 14 is a flow chart of a 1400 method modality for monitoring research spaces, as can be performed by a UE. In step 1410, the UE receives radio resource control (RRC) signaling and broadcast signal from a base station. In step 1420, the UE monitors a first research space for one or more
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39/44 more DCI messages according to configuration parameters specified by broadcast signaling. In step 1430, the UE monitors a second search space for at least one DCI message according to configuration parameters specified by the RRC signal. The second research space is a different type of research space than the first research space. In one embodiment, the first research space is a common research space and the second research space is an EU-specific research space.
[0064] Figure 15 is a flow chart of a 1500 method modality for monitoring research spaces, as can be performed by a UE. In step 1510, the UE receives a radio resource control (RRC) synchronization and signaling channel from a base station. In step 1520, the UE monitors a first search space for one or more DCI messages according to configuration parameters pre-associated with a cell identifier (ID) corresponding to the synchronization channel. In step 1530, the UE monitors a second search space for at least one DCI message according to configuration parameters specified by the RRC signal. The second research space is a different type of research space than the first research space. In one embodiment, the first research space is a common research space and the second research space is an EU-specific research space.
[0065] Figure 16 illustrates a block diagram of a 1600 processing system modality for performing methods described in this document, which can be installed on a host device. As shown, the
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40/44 processing 1600 includes a processor 1604, a memory 1606 and interfaces 1610-1614. Processor 1604 can be any component or set of components adapted to perform computations and / or other processing-related tasks, and memory 1606 can be any component or set of components adapted to store programs and / or instructions for execution by processor 1604. A means for configuring a context for a UE may include processor 1604. In one embodiment, memory 1606 includes a non-transient, computer-readable medium. The interfaces 1610, 1612, 1614 can be any component or set of components that allow the processing system 1600 to communicate with other devices / components and / or a user. For example, one or more of interfaces 1610, 1612, 1614 may be adapted to communicate data, control or management messages from processor 1604 to applications installed on the host device and / or on a remote device. As another example, one or more of the interfaces 1610, 1612, 1614 may be adapted to allow a user or user device (for example, personal computer (PC), etc.) to interact / communicate with the 1600 processing system. The processing system 1600 may include additional components not shown in Figure 16, such as long-term storage (e.g., non-volatile memory, etc.).
[0066] In some modalities, the 1600 processing system included in a network device that is accessing a telecommunications network or, on the other hand, a part of it. In one example, the
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41/44 processing 1600 is on a network-side device on a wireless or wired telecommunications network, such as a base station, a relay station, a programmer, a controller, a portal, a router, a data server applications, or any other device on the telecommunications network. In other embodiments, the 1600 processing system is on a user-side device that accesses a wireless or wired telecommunications network, such as a mobile station, user equipment (UE), a personal computer (PC), a tablet, a wearable communications device (for example, a smart wristwatch, etc.), or any other device adapted to access a telecommunications network.
[0067] In some embodiments, one or more interfaces 1610, 1612, 1614 connects the processing system 1600 to a transceiver adapted to transmit and receive signaling over the telecommunications network. Figure 17 illustrates a block diagram of a 1700 transceiver adapted to transmit and receive signaling over a telecommunications network. The 1700 transceiver can be installed on a host device. As shown, the transceiver
1700 comprises an interface of side from the Web 1702, one 1704 coupler, a transmitter 170 6, one receptor 1708, one processor sign 1710, and an interface side of 1712 device . The interface of side from the Web 1702 may
include any component or set of components adapted to transmit or receive signaling over a wireless and wired telecommunications network. The 1702 network-side interface can also include any component or set of components adapted to transmit or receive
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42/44 signaling via a short-range interface. The network side interface 1702 can also include any component or set of components adapted to transmit or receive signaling over a Uu interface. Coupler 1704 can include any component or set of components adapted to facilitate bidirectional communication through the network side interface 1702. The transmitter 1706 can include any component or set of components (eg elevator converter, power amplifier, etc.) adapted for converting a baseband signal to a modulated carrier signal suitable for transmission over the network side interface 1702. A means for transmitting an initial message from an access procedure may include transmitter 1706. Receiver 1708 may include any component or set of components (e.g., step-down converter, low-noise amplifier, etc.) adapted to convert a carrier signal received by the 1702 network-side interface into a baseband signal. A means of receiving mobile subscriber identifiers, initial downlink messages from access procedures, and requests forwarded for connection to a network may include receiver 1708.
[0068] The 1710 signal processor can include any component or set of components adapted to convert a baseband signal into a data signal suitable for communication via the 1712 device side interface (s), or vice versa . The 1712 interface (s) may include any component or set of components adapted to communicate data-signals between the 1710 signal processor and components within the device
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43/44 host (for example, the 1600 processing system, local area network (LAN) ports, etc.).
[0069] The 1700 transceiver can transmit and receive signaling by any type of means of communication. In some embodiments, the 1700 transceiver transmits and receives signaling wirelessly. For example, the 1700 transceiver may be a wireless transceiver adapted to communicate according to a wireless telecommunications protocol, such as a cellular protocol (for example, long-term evolution (LTE), etc.), a network protocol wireless local area (WLAN) (for example, Wi-Fi, etc.), or any type of wireless protocol (for example, Bluetooth, near field communication (NFC), etc.).
[0070] In such modalities, the network side interface 1702 comprises one or more antenna / irradiation elements. For example, the network side interface 1702 may include a single antenna, multiple separate antennas, or a multiple antenna array configured for multi-layer communication, for example, single input multiple outputs (SIMO), multiple inputs single output (MISO ), multiple inputs multiple outputs (MIMO), etc. In other modalities, the 1700 transceiver transmits and receives signaling through a wired medium, for example, twisted pair cable, coaxial cable, optical fiber, etc. Specific processing systems and / or transceivers may use all components shown, or only a subset of the components, and levels of integration may vary from device to device.
[0071] Although aspects of this disclosure have been described with reference to illustrated modalities, this
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44/44 description is not intended to be considered in a limitative sense. Various modifications and combinations of the illustrated modalities, as well as other modalities of this disclosure, will be evident to persons skilled in the art after reference to the description. It is intended, therefore, that the attached claims encompass any such modifications or modalities.

权利要求:
Claims (27)
[1]
AMENDED CLAIMS
1. Communication method characterized by the fact that it comprises:
receiving, by a user equipment (UE), from a network a first configuration signal that carries a first set of configuration parameters;
receive, by the UE, a second configuration signal from the network that carries a second set of configuration parameters;
monitor, by the UE, a first search space for a downlink control information message (DCI) according to the first set of configuration parameters; and monitor, by the UE, a second search space for the DCI message according to the second set of configuration parameters different from the first set of configuration parameters, each of the first set and the second set of configuration parameters comprising the at least one type of research space, a candidate number for one or more levels of aggregation and a set of control resources.
[2]
2. Method, according to claim 1, characterized by the fact that the second configuration signal is a broadcast signal.
[3]
3. Method, according to claim 2, characterized by the fact that the first configuration signal is a radio resource control (RRC) signal.
[4]
4. Method according to any one of claims 1 to 3, characterized by the fact that each
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2/7 of the first set and the second set of configuration parameters also comprises an association between the type of research space and the set of control resources.
[5]
5. Method according to any one of claims 1 to 4, characterized in that any of the first research space or the second research space is a common research space, an EU-specific research space, or a group-specific research space.
[6]
6. Wireless device characterized by the fact that it comprises:
one or more processors in communication with a non-transitory memory store comprising instructions, where the one or more processors are configured to execute the instructions to:
receive a first configuration signal that carries a first set of configuration parameters;
receiving a second configuration signal that carries a second set of configuration parameters;
monitor a first search space for a downlink control information (DCI) message according to the first set of configuration parameters; and monitor a second polling space for the DCI message according to the second set of configuration parameters different from the first set of configuration parameters, each of the first set and the second set of configuration parameters
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3/7 configuration comprising at least one type of research space, a candidate number for one or more levels of aggregation and a set of control features.
[7]
7. Wireless device according to claim
6, characterized by the fact that the second configuration signal is a broadcast signal.
[8]
8. Wireless device, according to claim
7, characterized by the fact that the first configuration signal is a radio resource control (RRC) signal.
[9]
Wireless device according to any one of claims 6 to 8, characterized by the fact that each of the first set and the second set of configuration parameters further comprises an association between the type of search space and the set of control features.
[10]
10. Wireless device according to any one of claims 6 to 9, characterized in that any of the first search space or the second search space is a common search space, an EU-specific search space, or a specific group research space.
[11]
11. Communication method characterized by the fact that it comprises:
transmit, through a network device, to a user device (UE) a first configuration signal that carries a first set of configuration parameters used to monitor a first search space for a downlink control information message (DCI) ); and
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4 / Ί transmit a second configuration signal to the UE that carries a second set of configuration parameters used to monitor a second search space for the DCI message, where the second set of configuration parameters is different from the first set of configuration parameters and each of the first set and the second set of configuration parameters comprises at least one type of search space, a candidate number for one or more levels of aggregation and a set of control resources.
[12]
12. Method according to claim 11, characterized by the fact that the second configuration signal is a broadcast signal.
[13]
13. Method, according to claim 12, characterized by the fact that the first configuration signal is a radio resource control (RRC) signal.
[14]
14. Method according to any one of claims 11 to 13, characterized by the fact that each of the first set and the second set of configuration parameters further comprises an association between the type of research space and the set of research resources control.
[15]
15. Method according to any of claims 11 to 14, characterized by the fact that any of the first research space or the second research space is a common research space, an EU-specific research space, or a group-specific research space.
[16]
16. Network device characterized by the fact that it comprises:
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5/7 one or more processors in communication with a non-transitory memory store comprising instructions, in which the one or more processors are configured to execute the instructions to:
transmitting to a user equipment (UE) a first configuration signal that carries a first set of configuration parameters used to monitor a first search space for a downlink control information (DCI) message; and transmit to the UE a second configuration signal that carries a second set of configuration parameters used to monitor a second polling space for the DCI message, where the second set of configuration parameters is different from the first set of configuration parameters and each of the first set and the second set of configuration parameters comprises at least one type of research space, a candidate number for one or more levels of aggregation and a set of control resources.
[17]
17. Network device according to claim
16, characterized by the fact that the second configuration signal is a broadcast signal.
[18]
18. Network device according to claim
17, characterized by the fact that the first configuration signal is a radio resource control (RRC) signal.
[19]
19. Network device according to any one of claims 16 to 18, characterized by the fact that
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6 / Ί each of the first set and the second set of configuration parameters further comprises an association between the type of research space and the set of control resources.
[20]
20. Network device according to any one of claims 16 to 19, characterized by the fact that any of the first search space or the second search space is a common search space, an EU-specific search space, or a specific group research space.
[21]
21. Wireless device characterized by the fact that it comprises:
means for receiving a first configuration signal that carries a first set of configuration parameters;
means for receiving a second configuration signal that carries a second set of configuration parameters;
means for monitoring a first polling space for a downlink control information (DCI) message according to the first set of configuration parameters; and means for monitoring a second polling space for the DCI message according to the second set of configuration parameters different from the first set of configuration parameters, each of the first set and the second set of configuration parameters comprising at least one type of research space, a candidate number for one or more levels of aggregation and a set of control resources.
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7/7
[22]
22. Wireless device according to claim
21, characterized by the fact that the second configuration signal is a broadcast signal.
[23]
23. Wireless device according to claim
22, characterized by the fact that the first configuration signal is a radio resource control (RRC) signal.
[24]
24. Wireless device according to any one of claims 21 to 23, characterized by the fact that each of the first set and the second set of configuration parameters further comprises an association between the type of search space and the set of control features.
[25]
25. Wireless device according to any one of claims 21 to 24, characterized in that any of the first search space or the second search space is a common search space, a UE-specific search space, or a specific group research space.
[26]
26. Apparatus characterized by the fact that the apparatus is configured to implement a method, as defined in any one of claims 1 to 5 and claims 11 to 15.
[27]
27. Computer program product characterized by the fact that it comprises instructions executable by computer stored in a non-transient computer-readable medium which, when executed by a processor, instruct the processor to implement a method, as defined in any one of claims 1 to 5 and from claims 11 to 15.

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同族专利:

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公开号 | 公开日

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US20180192405A1|2018-07-05|

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EP3556134A1|2019-10-23|

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WO2018127109A1|2018-07-12|

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CN111314037A|2020-06-19|

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EP3556134B1|2021-02-17|

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CN111314037B|2022-01-11|

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CN109347611B|2020-01-03|

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EP3556134A4|2019-12-11|

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AU2018206592A1|2019-08-15|

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CN109155931A|2019-01-04|

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EP3833091A1|2021-06-09|

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CN109347611A|2019-02-15|

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AU2018206592B2|2020-12-24|

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MX2019008189A|2019-12-02|

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法律状态:
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