harq signaling methods, base station and eu for non-grant uplink transmissions

专利摘要:
methods, base station, and eu for harq signaling for non-grant uplink transmissions in a wireless communication system, a non-grant uplink transmission is an uplink transmission sent from a user equipment (eu) to a base station that does not need an explicit and dynamic escalation grant from the base station. systems and methods are disclosed for executing hybrid automatic repeat request (harq) for non-grant uplink transmissions. ack / nack related signaling for harq as well as eu configuration related signaling for non-grant uplink transmission is also disclosed.
公开号:BR112019008988A2
申请号:R112019008988
申请日:2017-11-01
公开日:2019-10-01
发明作者:Ma Jianglei；Zhang Liqing；Cao Yu
申请人:Huawei Tech Co Ltd；
IPC主号:

专利说明:

METHODS, BASE STATION AND EU FOR HARQ SIGNALING FOR UPWARD TRANSMISSIONS WITHOUT CONCESSION
FIELD [001] The present request concerns uplink transmissions without concession.
BACKGROUND [002] In some wireless communication systems, user equipment (UE) communicates wirelessly with a base station to send data to the base station and receive data from the base station. Wireless communication from a UE to a base station is referred to as an uplink communication. Wireless communication from a base station to a UE is called downlink communication.
[003] Resources are needed to carry out uplink and downlink communications. For example, a UE can transmit data wirelessly to a base station on an uplink transmission at a particular frequency and for a certain time interval. The frequency and time interval used are examples of resources.
[004] Some wireless communication systems may support uplink transmissions on a concession basis. That is, if a UE wants to transmit data to a base station, the UE requests uplink resources from the base station. The base station grants the uplink resources, and then the UE sends the uplink transmission using the granted uplink resources. An example of uplink resources that can be granted by the base station
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2/156 is a set of time-frequency locations in an uplink orthogonal frequency division (OFDMA) multiple access frame.
[005] Some wireless communication systems may also, or instead, support uplink transmissions without concession. That is, a UE can send uplink transmissions using certain uplink resources possibly shared with other UEs, without specifically requesting the use of the resources and without specifically granting the resources to the base station. An uplink transmission without a concession does not need a dynamic and explicit scheduling concession from the base station.
[006] In some cases, when a UE sends an uplink transmission without a concession, the base station may not be able to decode the data on the uplink transmission.
SUMMARY [007] The hybrid automatic repeat request (HARQ) is a method in which the data to be transmitted is encoded using an error correction code. Then, if the encrypted data is corrupted during transmission and the receiver cannot correct the errors, the automatic retry request (ARQ) will be performed.
[008] HARQ signaling for uplink transmissions based on concession may not be available for uplink transmissions without concession because uplink transmissions without concession do not receive an explicit escalation concession from the base station.
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3/156 [009] The systems and methods are disclosed here to perform HARQ for uplink transmissions without concession. Signaling related to ACK / NACK for HARQ, as well as signaling related to the configuration of a UE for uplink transmission without concession, is also disclosed.
[0010] Using the systems and methods described here, HARQ signaling for uplink transmissions without concession can therefore be provided. In particular, some aspects below provide support for returning ACK / NACK for transmissions and retransmissions without concession.
[0011] In one aspect, a method performed by a base station is provided. The method includes the base station receiving a first uplink transmission without concession from a first UE. The method further includes the base station receiving a second uplink transmission without concession from a second UE. The method further includes transmitting, to the first UE and the second UE, a group ACK / NACK message indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to the second link transmission ascending without concession. A base station configured to execute the method is also disclosed.
[0012] In another aspect, a method provided by a first UE is provided. The method includes transmitting a first uplink transmission without concession to a base station. The method also includes receiving a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and
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4/156 an ACK or a NACK corresponding to a second uplink transmission without concession from a second UE. A UE to execute the method is also disclosed.
BRIEF DESCRIPTION OF THE DRAWINGS [0013] Modalities will be described, by way of example only, with reference to the attached figures, in which:
Figure 1 is a block diagram of a base station and a plurality of UEs, according to an embodiment;
Figure 2 is a block diagram showing a base station and UE in more detail, according to an embodiment;
Figure 3 illustrates examples of formats for an uplink transmission without concession;
Figures 4 and 5 illustrate tables showing examples of mappings between transmissions and signatures of MA or physical resources;
Figure 6 is a method performed by a base station, according to an embodiment;
Figure 7 illustrates an example of mapping between the MA subscription / access region without concession and the orthogonal return time-frequency / sequence location;
Figure 8 is a method performed by a UE and base station, according to an embodiment;
Figure 9 is a method performed by a UE and a base station, according to another embodiment;
Figures 10 to 13 illustrate examples of group ACK / NACKs;
Figure 14 is a method performed by a UE and a base station, according to another embodiment;
Figure 15 is a method performed by two UEs and one
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5/156 base station, according to one mode;
Figure 16 is a time-frequency resource partition showing a group acknowledgment for packets sent during the previous five time slots;
Figure 17 is a method performed by a UE and base station, according to another embodiment;
Figure 18 is a method performed by a UE and a base station, according to another embodiment; and Figure 19 is a method performed by a UE, according to one embodiment.
DETAILED DESCRIPTION [0014] For illustrative purposes, specific example modalities will now be explained in greater detail below in conjunction with the figures.
[0015] Figure 1 is a block diagram of a base station 100 and a plurality of UEs 102a-c, according to one embodiment.
[0016] The word base station encompasses any device that receives data wirelessly on the uplink from the UEs. Therefore, in some implementations, base station 100 may be called by other names, such as a transmit and receive point (TRP), a base transceiver station, a radio base station, a network node, a transmit / receive node , a Node B, an eNodeB (eNB), a gNB (sometimes called a gigabit Node B), a relay station or a remote radio terminal. In addition, in some embodiments, parts of base station 100 can be distributed. For example, some of the base station 100 modules may be located away from the equipment that houses the base station 100 antennas, and
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6/156 can be coupled to the equipment that houses the antennas through a communication link (not shown). Therefore, in some embodiments, the term base station 100 can also refer to modules on the network side that perform processing operations (for example, decoding and generating messages) that are not necessarily part of the equipment housing the base station's antennas. 100. The modules can also be coupled to other base stations.
[0017] In operation, UE 102a-c can each send uplink transmissions without concession to base station 100. An uplink transmission without concession is an uplink transmission that is sent using uplink resources not specifically granted to the UE by base station 100. An uplink transmission without a concession does not require an explicit and dynamic scheduling concession from base station 100.
[0018] Uplink transmissions without concession are sometimes called transmissions without concession, without scaling or with little scaling, or transmissions without concession. Uplink transmissions without concession from different UEs 102a-c can be transmitted using the same designated resources, in which case uplink transmissions without concession are competition-based transmissions. Uplink transmissions without concession may be suitable for transmitting intermittent traffic with short packets from UEs 102a-c to base station 100, or for transmitting data to base station 100 in real time or with low latency. Examples of applications in which a
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7/156 uplink transmission scheme without concession can be used include: massive machine type communication (m-MTC), ultra-reliable low latency communications (URLLC), smart electric meters, smart grid teleprotection and autonomous steering. However, uplink transmission schemes without concession are not limited to these applications.
[0019] The uplink resources on which transmissions without a concession are sent will be called uplink resources without a concession. For example, uplink resources without a concession may be a region designated in an OFDMA framework. UE 102a-c can use the designated region to send its uplink transmissions without concession, but base station 100 does not know which of the UEs 102a-c, if any, will send an uplink transmission without concession in the designated region .
[0020] Uplink resources without concession can be predefined, for example, known in advance to both UEs and base station 100. Uplink resources without concession can be static (never change), or link resources ascending without concession can be configured semi-statistically. A semi-static configuration means that it is configured once and can only be updated / changed slowly, such as once in many frames or only updated as needed. A semi-static change differs from a dynamic change in that a semi-static change does not occur as often as a dynamic change. For example, a dynamic change / update can
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8/156 refer to a change in each subframe or every few subframes, and a semi-static change can refer to a change that occurs only once every several OFDM frames, once every few seconds or update only if required.
[0021] In some embodiments, uplink resources without a concession can be pre-configured, for example, there can be a plurality of predefined uplink resource partitions, and the base station 100 or the network can choose semi- statically uplink resource partitions and signal to UEs the uplink resource partition without concession being used. In some embodiments, the base station 100 or UEs can be configured during manufacture to know which uplink resources to use as uplink resources without concession, for example, through predefined tables loaded during manufacture. In some embodiments, uplink resources without concession can be configured semi-statically, for example, using a combination of broadcast signaling, upper layer signaling (RRC signaling) and dynamic signaling (for example, DCI) by base station 100. For dynamically signaling uplink resources without concession, the base station 100 or the network can adapt to the system traffic load of the UEs. For example, more uplink resources without a concession can be allocated when more UEs are served that can send uplink transmissions without a concession. In some embodiments, a control node (for example, a computer) on the network can determine the
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9/156 uplink resources without concession to be used. The network can then display uplink resources without concession to the base station and UEs. In some embodiments, a UE operating in non-concession mode can be configured semi-statically to combine: 1) RRC signaling information and system information; or
2) RRC signaling information and DCI information; or
3) RRC signaling information, system information and DCI information to determine an assigned transmission resource.
[0022] Figure 1 illustrates a message 150 being sent by UE 102a in an uplink transmission without concession through the uplink channel 156. The message 150 is transmitted using a multiple access (MA) resource. An MA resource consists of a physical MA resource (for example, a time-frequency block) and at least one MA subscription. The MA subscription can include (but is not limited to) at least one of the following: a coding table / codeword, a sequence, an interval or mapping pattern, a pilot, a demodulation reference signal (for example , a reference signal for channel estimation), a preamble, a spatial dimension and a power dimension. The term pilot refers to a signal that includes at least one reference signal, for example, a demodulation reference signal. The reference signal can be the MA signature. In some embodiments, the pilot may include the demodulation reference signal, possibly together with a preamble oriented to channel estimation, or a preamble of random access channel (LACH-like RACK).
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10/156 [0023] In some modalities, uplink transmissions may use non-orthogonal multiple access (NOMA), such as: scarce code multiple access (SCMA), interleaving grid multiple access (IGMA), shared access with multiple user (MUSA), low code rate spread, frequency domain spread, non-orthogonal coded multiple access (NCMA), pattern division multiple access (PDMA), resource spread multiple access (RSMA), low density with subscription vector extension (LDS-SVE), shared access based on subscription and low code rate (LSSA), non-orthogonal encrypted access (NOCA), interleaving division multiple access (IDMA), multiple division access repetition (RDMA) or group orthogonal coded access (GOCA). Depending on the multiple access method used, the MA subscription can take different forms. The MA subscription can be related to the specific format used for the multiple access method. For example, if SCMA is used, then the MA signature for uplink transmission can be the SCMA encoding table used for uplink transmission. As another example, if IGMA is used, then the MA signature for the uplink transmission can be the IGMA signature, interleaving pattern or grid mapping used for the uplink transmission.
[0024] Figure 2 is a block diagram showing the base station 100 and UE 102a of Figure 1 in more detail. Base station 100 includes a non-leased transmission module 104 for processing non-leased transmissions
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11/156 received from UEs 102a-c and to participate in the HARQ methods described here regarding non-concessioned transmissions received. For example, the non-grant transmission module 104 may include a non-grant transmission decoder 206. The base station further includes an encoder 210 for encoding information, such as downlink control (DCI) information, for UEs 102ac. Base station 100 also includes a receiver 209 for receiving uplink transmissions from UEs 102a-c and a transmitter 211 for sending messages to UEs 102a-c on the downlink. One or more antennas are coupled to receiver 209 and transmitter 211. Only one antenna 208 is illustrated. Base station 100 further includes memory 204. Base station 100 also includes other components for operation, for example, to implement the physical layer, but these have been omitted for the sake of clarity.
[0025] The transmission module without concession 104 and its components (for example, the transmission decoder without concession 206), as well as the encoder 210 and processing components of receiver 209 and transmitter 211, can be implemented by one or more processors that execute instructions that cause one or more processors to perform the operations of encoder 210, receiver 209, transmitter 211 and transmission module without concession 104 and its components. Alternatively, the encoder 210, the receiver 209, the transmitter 211 and the transmission module without concession 104 and its components can be implemented using dedicated integrated circuits, such as an application-specific integrated circuit (ASIC), a graphics processing unit (GPU), or a
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12/156 programmable programmable field gate array (FPGA) to perform the operations of encoder 210, receiver 209, transmitter 211, and the non-concession transmission module 104 and its components.
[0026] UE 102a also includes a transmission module without concession 106 to generate and send messages without concession and to participate in the HARQ methods described herein related to messages without concession. For example, the non-leased transmission module 106 includes a non-leased message generator 214 for generating messages to be transmitted in non-leased uplink transmissions. The generation of a message without concession may include the encoding, in the 219 encoder, of the data to be transmitted in the message and the modulation of the encoded data. UE 102a further includes a decoder 218 for decoding information from base station 100, for example for decoding DCI that has been encoded by encoder 210. UE 102a further includes a transmitter 215 for transmitting uplink transmissions and a receiver 217 for receive messages from base station 100 on the downlink. One or more antennas are coupled to transmitter 215 and receiver 217. Only one antenna 216 is illustrated. UE 102a also includes 212 memory. UE 102a also includes other components for operation, for example, to implement the physical layer, but these have been omitted for the sake of clarity.
[0027] The transmission module without concession 106 and its components (for example, the message generator without concession 214), as well as the decoder 218 and processing components of transmitter 215 and receiver 217, can
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13/156 be implemented by one or more processors that execute instructions that cause one or more processors to perform the operations of decoder 218, transmitter 215, receiver 217 and the transmission module without concession 106 and its components. Alternatively, the decoder 218, the transmitter 215, the receiver 217 and the transmission module without concession 106 and its components can be implemented using dedicated integrated circuits, such as an ASIC, GPU or a FPGA programmed to perform the decoder operations 218, transmitter 215, receiver 217 and the transmission module without concession 106 and its components.
Example of Message Formats for Uplink Transmissions Without Concession [0028] Figure 3 illustrates example formats for message 150 sent by UE 102a in uplink transmission without concession in Figure 1. The sample formats are shown in a dotted bubble 124.
[0029] In example 126, message 150 includes a signature from MA 152, as well as data 154 and a UE ID 156. UE ID 156 is information used by base station 100 to identify the UE. In example 126, data 154 and UE ID 156 are encoded together, and a corresponding cyclic redundancy check (CRC) 158 is generated and included in message 150. In some embodiments, UE ID 156 is incorporated (for example, scrambled) on the CRC 158, which can reduce the size of the payload. If the UE ID 156 is embedded in the CRC 158, then the base station 100 needs to know the UE ID or perform blind detection using all potential UE IDs to decode the CRC 158.
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14/156 [0030] Example 128 is a variation of example 126 where UE ID 156 is encoded separately from data 154. Therefore, a separate CRC 160 is associated with UE ID 156. In some embodiments, UE ID 156 it can be within one or more other headers, in which case the CRC 160 is for the headers in which the CRC 160 is located. In example 128, UE ID 156 can be transmitted with a modulation and encoding scheme (MCS) lower than data 154 to facilitate the decoding of UE ID 156. There may be situations where UE ID 156 is successfully decoded , but data 154 is not successfully decoded.
[0031] In examples 126 and 128, the signature of MA 152 is illustrated as occupying time-frequency resources separate from data 154, for example at the beginning of message 150. This may be the case if, for example, the signature of MA 152 consists of a reference signal or a preamble. However, the MA 152 signature may instead be part of the transmission scheme itself, for example, the coding table used or the mapping or collation pattern used, in which case the 152 signature would not take up time- separate frequency from data 154. Also, in modalities where the MA 152 subscription occupies separate time-frequency resources from data 154, the resources need not necessarily be at the beginning of message 150.
[0032] Example 130 in Figure 1 shows a variation in which UE ID 156 and data 154 are transmitted via different resources. For example, UE ID 156 can be transmitted as part of a control channel, such as a physical uplink control channel (PUCCH). The
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15/156 data 154 can be transmitted in a region without granting an uplink data channel. The MA signature is not illustrated in example 130, but the MA signature would be part of the data transmission.
[0033] In some other modalities, the UE ID is not explicitly transmitted. For example, in some URLLC scenarios, based on the configuration of the reference signal and resource, the detection of the reference signal together with information about resources without concession may be sufficient to identify the UE. In this case, the UE ID does not need to be explicitly transmitted, and the base station can identify the UE after successfully detecting the reference signal. An example is shown in 132. Only the signature of MA 152 and data 154 is included in the message, not a UE ID. The UE ID can be determined based on the MA 152 signature and the non-concession uplink resources used to send the message.
[0034] When the UE sends message 150 to base station 100, base station 100 first attempts to detect the MA signature. MA signature detection can involve a blind detection process in which the MA signature is detected among all possible MA signature choices. Detecting the MA signature is referred to as activity detection. As an example, the MA signature on the uplink transmission without concession can be a reference signal and the detection of activity by the base station therefore comprises the detection of the reference signal on the uplink transmission without concession. As another example, the MA subscription on the uplink transmission without a concession may be a
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16/156 combination of the reference signal and the coding or signature table used by the UE in uplink transmission without concession, and the activity detection by the base station therefore comprises the combination of the reference signal and the coding / signature table used in uplink transmission without concession.
[0035] Upon successfully performing activity detection, base station 100 knows that a UE has sent an uplink transmission without a concession. However, successful activity detection may or may not reveal the identity of the UE to base station 100. If there is a unique mapping between a UE and an MA signature (for example, for a given physical MA resource, each UE has been designated to use a different MA signature), successful activity detection reveals the identity of the UE that sent the uplink transmission without concession. Otherwise, in general, successful activity detection does not reveal the identity of the UE that sent the uplink transmission without a concession, although it may reveal that the UE is from a particular group of UEs, if different groups of UEs have signatures different MA. In some embodiments, activity detection may also include obtaining the UE ID, for example, if the UE ID is encoded separately from data 154, as in example message 128.
[0036] After activity detection is successful, base station 100 then attempts to estimate the channel based on the MA signature and optionally additional reference signals multiplexed with the data message, and then decode the data 154. If the decoding of
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17/156 data is also successful, then base station 100 can send an acknowledgment (ACK) to the UE on the downlink, indicating that base station 100 has successfully decoded data 154. In modalities in which activity detection successful does not reveal the identity of the UE, successful decoding of the rest of message 150 will reveal the identity of the UE, in which case base station 100 will know the UE to which to send the ACK. If the data decoding is not successful, a negative acknowledgment (NACK) may be sent by the base station, possibly with a lease for a retransmission. As discussed in more detail later, in some modalities, a NACK is not sent if the data decoding was not successful. As also discussed in more detail later, in some modalities, if a NACK is sent, the NACK may not necessarily include information that can uniquely identify the UE to which the NACK is being sent because the base station may not be able to uniquely identify the UE.
[0037] In one example, the signature of MA 152 in example 126 is a reference signal. Base station 100 can first successfully perform activity detection by successfully decoding the sequence of reference signals. The sequence of reference signals can then be used by the base station 100 to estimate the channel of the uplink channel 156. To facilitate successful decoding of the reference signal, the reference signal can be transmitted with a low MCS. Once the reference signal is successfully decoded and the channel estimate is performed, base station 100 then decodes the load
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18/156 with data 154 and UE ID 156. Base station 100 can read UE ID 156 to be informed which UE the transmission without concession came from. Base station 100 can then send an ACK to the UE on the downlink, indicating that base station 100 has successfully decoded data 154.
Base station UE identification [0038] The uplink transmission without a concession may include a UE ID, for example, UE ID 156 in Figure 3. The UE ID is the information used by the base station 100 to identify the UE.
[0039] In some embodiments, the UE ID can be a temporary radio network identifier (RNTI), or it can be based on an RNTI.
[0040] In some embodiments, the UE ID can be an index. The index distinguishes the UE from other UEs that are also authorized to send uplink transmissions without concession on the same uplink resources without concession. For example, the index can distinguish the UE from other UEs that are also allowed to send uplink transmissions without concession in a shared frequency range region in the same time slot, transmission time slot (TTI) or subframe.
[0041] In some modalities, the UE ID does not have to be identical or fixed in a cell or area serving. For example, if a particular UE is part of a group of ten UEs authorized to send uplink broadcasts without concession on the uplink resource partition A, then the UE ID can be an index between 1 and 10, which distinguishes the UE of the other nine UEs in the group. Base station 100 uses the index and knowledge of which link resource partition
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19/156 uplink without concession was used to determine which particular UE sent the uplink transmission without concession.
[0042] In some embodiments, for a given MA physical resource, UEs that use that physical MA resource for uplink transmissions without concession receive different MA subscriptions. Base station 100 can then uniquely identify the UE that sent the uplink transmission without concession based on the combination of the MA signature and the physical MA resource used.
[0043] In some modalities, for a given physical MA resource, some of the UEs that use this physical MA resource for uplink transmissions without concession may use the same MA subscription. A UE index can be assigned by base station 100 to differentiate between UEs that use the same MA signature. For example, if two UEs use the same MA signature, then one of the UEs can receive the UE 1 index as their UE ID, and the other UE can receive the UE 2 index as their UE ID. Indexes 1 and 2 can be reused for other UEs that share the same MA signature. Then, the base station 100 uses the combination of the physical MA resource, the MA signature and the UE index to identify the UE that sent the uplink transmission without concession.
[0044] In some embodiments, each UE can be assigned the use of a different MA signature which is known to base station 100 and the UE. The assignment may change over time. For example, a UE can be assigned to a first MA subscription and later the UE can receive another
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20/156 signature of MA. The MA subscription received and the time-frequency resource used can uniquely identify the UE.
[0045] In some embodiments, a particular UE can be assigned with multiple MA signatures, for example, a first MA signature for initial transmissions and a second MA signature for retransmissions. In some embodiments, the MA signature assigned to each UE in a group of UEs may change over time according to a jump pattern. In some embodiments, the assignment of MA signatures to the UEs can be reused or repeated for different UEs in different uplink resource partitions without concession. For example, a first group of UEs can be assigned to a first uplink resource partition to send its uplink transmissions without concession. Each EU in the first group of UEs can receive a different MA subscription. A second group of UEs can be assigned to a second uplink resource partition to send its uplink transmissions without concession. Each UE in the second group of UEs can receive a different MA subscription. The MA signatures in the first group may overlap the MA signatures in the second group, in order to uniquely identify the UE, the base station 100 must know both the uplink transmission MA signature and the link resource partition uplink used to send the uplink transmission without concession. For example, base station 100 can use detected MA signature 152 and an index corresponding to the uplink resource partition without concession used to check a lookup table to determine the
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21/156 identity of the UE that sent the uplink transmission without concession.
[0046] In modalities where base station 100 can determine the identity of the UE without the UE ID 156, then the UE ID 156 may not even need to be transmitted as part of message 150.
[0047] In summary, there are several possibilities in the implementation to allow base station 100 to uniquely identify the UE that sent the uplink transmission without concession. For example, if only one UE is able to use an uplink resource without a particular concession, then the use of that uplink resource without a concession uniquely identifies the UE. As another example, when there is a unique mapping of MA signatures to UEs for a specific resource region, the MA signature can uniquely identify a UE in that resource region. As another example, when a UE ID is present in the uplink message and successfully decoded by the base station, the UE ID itself can uniquely identify the UE, or the UE ID in combination with other information (for example, the link resource ascending without used concession) can uniquely identify the UE.
HARQ for uplink transmissions without concession [0048] HARQ can be performed for uplink transmissions without concession. For example, if data 154 on the uplink transmission without initial concession is not successfully decoded by base station 100, then a retransmission can be performed by the UE. The retransmission may include a retransmission of the data
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22/156 initials or additional information to decode the initial data. For example, the retransmission data may include some or all of the original data or parity information. Base station 100 can perform the HARQ combination as follows: instead of discarding unsuccessful initial data decoded, unsuccessful initial data can be stored in base station 100 in memory and combined with received relay data to try to decode with initial data successfully. When the HARQ combination is performed, the retransmission data from the UE may not need a complete retransmission of the initial data. The retransmission can carry less data, such as some or all of the parity bits associated with the initial data. One type of HARQ combination that can be used is the flexible combination, such as chase combination or incremental redundancy.
[0049] Initial transmissions and retransmissions can use different versions of redundancy (RVs). When the data is encoded in the message generator without concession 214, the encoded bits can be partitioned into different sets (which possibly overlap each other). Each set is a different RV. For example, some RVs may have more parity bits than other RVs. Each RV is identified by an RV index (for example, RV 0, RV 1, RV 2, ... etc.). When an uplink transmission is sent using a particular RV, then only the encoded bits corresponding to that RV are transmitted. Different channel codes can be used to generate the encoded bits, for example, turbo codes, low density parity check codes (LDPC), codes
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23/156 polar, etc. An error control encoder (not shown) in the non-compromised message generator 214 at UE 102a can perform channel encoding.
[0050] In one embodiment, channel encoding results in an encoded bit stream comprising streams of three bits: a systematic bit stream and two streams of parity bits. Rate matching can be performed and a circular buffer (not shown) can store systematic and parity bits. The bits can be read from the circular buffer and modulated for transmission in the uplink message without concession. The circular buffer has different RVs associated with it, for example, four versions of redundancy (RVs): RVO, RV1, RV2 and RV3. Each RV indicates a starting location from which the encoded bits are to be read from the circular buffer. Therefore, each RV transmits a different set of the encoded bits. Data can initially be transmitted using RV 0, but a retransmission can sometimes use a higher RV, for example, RV 2 for the first retransmission, RV 3 for a second retransmission, etc.
[0051] Base station 100 uses VR knowledge to perform decoding. For the chase combination, the RV of the initial retransmissions can be the same, for example, RV 0. For incremental redundancy, the retransmissions can use a larger RV that can follow a fixed pattern, for example, RV 0 for the initial transmission, RV 2 for the first retransmission, RV 3 for the second retransmission and RV 1 for the third retransmission. Therefore, in order to decode the data, it may be necessary for the base station 100 to know the VR index of the data being received on a
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24/156 uplink transmission without concession, unless there is only one predefined RV.
[0052] As part of the HARQ procedure for an uplink transmission without a concession, an ACK can be sent by the base station 100 when the base station 100 successfully decodes the uplink transmission data without a concession. In some embodiments, a NACK can be sent by base station 100 when the data is not successfully decoded. However, a NACK cannot always be sent, for example, in HARQ schemes without NACK in which the absence of an ACK within a predetermined period of time is interpreted as a NACK. In some embodiments, an ACK may be associated with a UE ID that identifies the UE for which the ACK is intended. If the resource region without granting uplink and MA signature used can together uniquely identify the UE, then the ACK may instead be associated with an index that identifies the MA signature. The UE knows that the ACK is intended for it based on a corresponding MA subscription index. A NACK, if sent, can be associated with a UE ID when the UE ID is successfully decoded by the base station. Alternatively, NACK can be associated with an index identifying the MA signature corresponding to the uplink transmission being NACK'd, assuming successful detection of activity by the base station. Otherwise, the NACK may not be associated with an UE ID or MA subscription.
Retransmissions and Mapping for MA Signatures [0053] If the data on the uplink transmission without initial concession is not successfully decoded
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25/156 by the base station, then a retransmission can be performed by the UE. In some embodiments, the MA signature used in uplink transmission without a concession can identify whether the transmission is an initial transmission or a retransmission. In some embodiments, the MA signature can also or instead be used to identify the UE that sends the transmission.
[0054] As a first example, Figure 4 illustrates three tables 302, 304 and 306, showing different mappings. In table 302, the MA signature is a reference signal. A set {P} of nine reference signals (ie, nine MA signatures) is partitioned into three sets {Pl}, {P2} and {P3}. The reference signals can be pilots. Each row in table 302 represents a tuple-3. In this example, the set {P} is divided into three exclusive sets {Pl}, {P2} and {P3}, so that each set has three of the nine reference signals. Specifically, {Pl} includes the reference signals pll, p! 2 and p! 3, {P2} includes the reference signals p21, p22 and p23 and {P3} includes the reference signals p31, p32 and p33. Three of the nine reference signals are designated as initial reference signals, another three of the nine reference signals are designated as first relay reference signals, and the last three of the nine reference signals are designated as second relay reference signals. The specific mapping in table 302 is just an example, and the mapping may change over time or it may be just for an uplink resource partition without particular concession (for example, there may be a different mapping on a different physical MA resource ). In the example in table 302,
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26/156 UE 102a is assigned to tuple index 1, UE 102b is assigned to tuple index 2, and UE 102c is assigned to tuple index 3. Therefore, when base station 100 performs activity detection well successful (i.e., successfully decodes the reference signal), then base station 100 uses the sequence of reference signals to determine which UE sent the uplink transmission without concession. In the example in table 302, each reference signal sequence also indicates to base station 100 whether the uplink transmission without concession is an initial transmission, a first retransmission or a second retransmission. In the example in Table 302, the reference signal can be used to identify both the initial and the retransmission, as well as the identity of the UE. For example, the reference signal pll, p21 or p31 can indicate that packets without a concession are transmitted by UE 102a. In alternative modalities, there may still be a unique mapping between reference signals and UEs, but the reference signals can only be mapped to the identity of the UE and not mapped to initial transmissions or retransmissions. For example, the reference signal pll can be assigned to a first UE, the reference signal pl2 can be assigned to a second UE, ..., and the reference signal p33 can be assigned to a ninth UE. Each of the nine UEs can then use their same assigned reference signal for their initial transmissions and retransmissions.
[0055] Table 304 is the same as table 302, except that the MA signature is a sparse code multiple access coding table (SCMA). Nine tables of
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27/156 SCMA coding {A1, A2, A3, Bl, B2, B3, Cl, C2 and C3} are divided into sets of initial and retransmission and assigned to each of the UEs 102a-c. For example, the use of the codebook A1 indicates to base station 100 that UE 102a has sent the transmission, and that the transmission is an initial data transmission. In some embodiments, there may also be a fixed, semi-persistent or dynamic association between certain reference signals and SCMA coding tables. In such embodiments, the reference signal sequence or the SCMA coding table can be used to identify the UE or whether the transmission is an initial transmission, a first retransmission or a second retransmission. In some embodiments, an SCMA coding table may be associated with multiple reference signals. In such embodiments, the identification of the reference signal sequence reveals the SCMA coding table used. In some embodiments, the SCMA coding table may have a one-to-one association with the reference signal. In such embodiments, the identification of the reference signal sequence reveals the SCMA coding table used and vice versa.
[0056] Table 306 is also the same as table 302, except that instead of MA signatures, there is a mapping assigned between physical uplink resources used for non-concession transmissions and initial transmissions and retransmissions and UEs. Nine different time-frequency locations (A1, A2, A3, Bl, B2, B3, Cl, C2 and C3] are partitioned into initial and retransmission sets and assigned to each of the UEs 102a-c. For example, the reception by base station 100 of a
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28/156 uplink transmission without concession on physical uplink resources Al indicates to base station 100 that UE 102a has sent the transmission and that the transmission is an initial data transmission.
[0057] In each table shown in Figure 4, there is a unique mapping between MA signature tuples or physical resource tuples and the UEs. However, in some modalities, there needs to be no single mapping for the UEs. The base station does not need to assign UEs to particular tuples. More generally, the mapping relationship between the different MA signatures or physical resources, that is, the tuples in the tables in Figure 4, can be used to identify that the initial transmission and retransmissions belong to the same packet. For example, UE 102a can randomly select index tuple 1 in table 302 (pll, p21, p31) for a first data packet to be transmitted to base station 100, and UE 102a can randomly select index tuple 2 (pl2, p22, p32) for a second data packet to be transmitted to base station 100. In some embodiments, a UE can choose or be configured to use different tuples for different packets. In some modalities, two UEs can choose the same tuple, for example, if they randomly select the MA signatures for the initial transmission, which can occur in mMTC applications.
[0058] In some modalities, there may be a first MA signature used for an initial transmission of a packet, and a second MA signature used for all K retransmissions of that packet, where K is greater than or equal to one. For example, table 308 in Figure 5 illustrates a
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29/156 example where MA signatures are reference signs. A set {P} of eight reference signals is partitioned into two sets {Pl} and {P2}. The reference signals can be pilots. Each row in table 308 represents a tuple
2. Tuples-2 are not only assigned to particular UEs, instead, each UE in a group of UEs can randomly select which tuple-2 to use. {PI} is a set of initial transmission reference signals and includes reference signals pll, p! 2, p! 3 and p! 4. {P2} is a set of retransmission reference signals and includes reference signals p21, p22, p23 and p24. When a UE must transmit a packet using an uplink transmission without concession, the UE uses one of the four tuple2s. The tuple-2 used indicates which reference signal is used for the initial transmission and which reference signal is used for any and all retransmissions. For example, if UE 102a uses tuple-2 indicated by index 2 to transmit a packet, then the reference signal used for the initial transmission of the packet is p! 2, and the reference signal used for any and all retransmission of the package is p22.
[0059] In the modality described above in relation to Figure 5, the MA signature used identifies whether the uplink transmission without concession is an initial data transmission or a data retransmission. However, if K> 1, then the MA retransmission signature does not reveal whether it is a first relay, second retransmission, etc., since the same MA signature is used for all data retransmissions.
Redundancy Version Identification [0060] In some modalities, there may be a mapping
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30/156 between MA signatures and RVs that can allow base station 100 to determine the uplink transmission RV
without concession, so that the RV do not have what to be explicitly signaled. [0061] By example, can be pre- configured what each transmission of uplink without concession can use
only one of the two RVs (for example, RV 0 or RV 1). A first MA subscription is mapped to a first RV, such that when the base station receives the first MA subscription, the base station knows that the uplink transmission data without a concession has the first RV. A second MA subscription is mapped to a second RV, such that when the base station receives the second MA subscription, the base station knows that the uplink transmission data without concession has the second RV.
[0062] As a more specific example: each uplink transmission without concession can use only one of the two RVs; when a UE must transmit a packet using an uplink transmission without concession, the UE uses one of the four tuples-2 of Figure 5; the reference signal in tuple-2 that is used for the initial transmission is mapped to the first VR, and the reference signal in tuple-2 that is used for the retransmission (s) is mapped to the second VR. Then, when the base station 100 receives an uplink transmission without a concession, the base station 100 knows of the MA subscription used if the uplink transmission without a concession is an initial transmission or retransmission of data, and what is the RV for the uplink transmission without concession.
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31/156 [0063] In some embodiments, there may be a first MA signature used for an initial data transmission and a second MA signature used for all retransmissions of that data, for example, as in Figure 5, but there may be more than than two possible RV values that can be used. In such embodiments, the MA signature can still be used to determine whether the uplink transmission without a concession is an initial transmission or a retransmission. VR can then be identified based on this information, as well as based on a resource jump pattern.
[0064] As an example, the receipt of a uplink transmission without a concession having a first MA subscription reveals to the base station 100 that the uplink transmission without a concession is an initial data transmission. The leased link uplink resource used to send the leased link uplink transmission reveals to base station 100 that the UE that sent the uplink transmission without leased is using a particular resource hop pattern known in advance to the UE and base station. The resource hop pattern specifies the resources used for the initial transmission and any retransmissions, and there is also a known mapping between the resource hop pattern and the RV used for the initial transmission and each retransmission. Therefore, the base station can obtain from the mapping the VR of the uplink transmission without initial concession and the VR of all future uplink retransmissions without concession of this data.
[0065] As another example, the reception of a transmission
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32/156 uplink without concession with a second MA subscription reveals to base station 100 that uplink transmission without concession is a data retransmission. Base station 100 has no record of a previous retransmission of the data, or even an initial transmission of the data. Base station 100 decides that the activity detection of the initial transmission must have failed and assumes that the received transmission is a first retransmission of the data. The uplink resource without concession, used to send the first retransmission, reveals to base station 100 that the UE is using a particular resource hop pattern known in advance to the UE and the base station. The resource hop pattern specifies the resources used for the initial transmission and any retransmissions, and there is also a known mapping between the resource hop pattern and the RV used for the initial transmission and each retransmission. Therefore, the base station can obtain from the mapping of the RV of the first retransmission and of the RV of all future uplink retransmissions without granting such data.
[0066] As another example, the time interval used by the UE to send the uplink transmission without concession can correspond to a respective RV based on a mapping known to both the UE and the base station. As a result, the length of time during which the uplink transmission without a concession is received by the base station therefore reveals to the base station the RV used in the transmission. For example, it can be configured in advance that when sending a transmission of
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link ascending without concession on one interval in time odd, the EU uses VR 0 and when you send a transmission of link ascending without concession on one interval in time couple, the EU uses VR 1.
[0067] Figure 6 is a method performed by base station 100, according to one modality. In step 402, the base station receives an uplink transmission without concession from UE 102a. Uplink transmission without a concession uses an MA subscription. In step 404, the base station 100 determines the data RV in the uplink transmission without concession, using the MA signature. In step 406, base station 100 attempts to decode the data on the uplink transmission without concession based on the RV.
[0068] Step 404 may include the use of the MA signature to determine whether the uplink transmission without concession is an initial data transmission or a retransmission of the data, and then obtain the VR based on the uplink resource without concession used by the UE and the determination of whether the uplink transmission without concession is an initial data transmission or a retransmission of the data.
ACK / NACK signaling [0069] There are many different possibilities for signaling an ACK or a NACK (when used) to a UE that sent an uplink transmission without a concession. Different options are described below. A combination of two or more of the options described below can be used. In addition, some of the options described below assume that the base station first uniquely identified
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34/156 the UE that sent the uplink transmission without concession. Different ways in which the UE can be uniquely identified are described earlier, for example, using the UE ID (which can be an index), or using the UE ID in combination with other information, such as the uplink resource without concession used, or using the MA subscription in combination with the ubiquitous uplink feature used, etc. Note that the ACK / NACK described here may not always be explicitly indicated, but it may include an ACK / NACK that is implicitly indicated by a stagger grant. For example, sometimes the HARQ return is a staggering concession that is staggering a retransmission of the same transport block (TB) as the transmission without a concession, which may implicitly indicate that the transmission without a previous TB concession is not successful. successful (ie a NACK). In another example, the base station may send a HARQ return to the UE that contains a staggering concession for a new TB using the same HARQ process number as the non-concession transmission, in which case, the concession may be considered includes an implicit ACK for transmission without granting TB sharing the same HARQ process.
One option - Dedicated downlink recognition channel [0070] In some embodiments, base station 100 can transmit ACKs or NACKs for uplink transmissions without concession on a dedicated downlink recognition channel. In some embodiments, the dedicated downlink recognition channel can be implemented in a similar way to the
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Physical HARQ (PHICH) in LTE, in which case the dedicated downlink recognition channel can be referred to as the PHICH type channel.
[0071] In some modalities, the return delay on the dedicated downlink recognition channel has a fixed relationship with the resource access delay without concession. For example, if a UE sends an uplink transmission without concession in the subframe (or TTI) w, then the ACK / NACK for that uplink transmission without concession is sent in the dedicated downlink recognition channel in the subframe (or TTI ) w + k. Ideally k is small, for example, k = 2. For example, if the UE should automatically send retransmissions until an ACK is received, then having a small k value, we expect it to result in early termination of automatic retransmissions. In some embodiments, the value of k is predefined and known to the UE and the base station. For example, the k value can be configured in the system information. In some other modalities, the k value can be configured for each UE or group of UEs, and the configuration can be done through signaling, for example, RRC signaling.
[0072] In some embodiments, the ACK / NACK return to a particular UE is sent on the dedicated downlink recognition channel using a particular orthogonal sequence. For example, the ACK / NACK return to a UE may be a bit that is repeated (to add redundancy) and then modulated using binary phase shift (BPSK) switching to result in a group of symbols. The symbol group is then multiplied using
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a sequence specific orthogonal. At exits of these belonging to same groups of resources or places of time- frequency are multiplexed together. a shuffle
cell-specific can then be applied, followed by mapping to various resource elements. The UE requires knowledge of which orthogonal sequence was used to correctly decode the ACK / NACK return. For example, the UE can perform an orthogonal sequence correlation with the received return signal to decode the ACK / NACK return. The orthogonal sequence is sometimes called an orthogonal code.
[0073] In some modalities, there is a known mapping between (i) the MA signature or the resources without concession used by a UE to send the uplink transmission without concession and (ii) the orthogonal sequence used by the base station to send the ACK / NACK return or the time-frequency location on the dedicated downlink recognition channel on which the ACK / NACK return is sent. The mapping can be predetermined in advance and can be stored in the form of a lookup table in the memory of the UEs and base station.
[0074] In some embodiments, the combination of the particular MA signature used by the UE and the resource region without granting a particular uplink used by the UE is indexed by (m, n), where m identifies the specific MA signature used by the UE. UE, and identifies in the resource region without granting uplink used by the UE. The value (m, n) is mapped to a particular orthogonal sequence used for the ACK / NACK return and to a specific time-frequency location of the ACK / NACK return in the
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37/156 dedicated downlink recognition channel. In some embodiments, the particular time-frequency location of the ACK / NACK return on the dedicated downlink recognition channel is called a PHICH resource group.
[0075] As an example, table 420 in Figure 7 illustrates an example of mapping between (i) the MA signature (m) and the non-concession access region (n) used by the UE, and (ii) the orthogonal sequence used for the ACK / NACK return for that UE and the time-frequency location of that ACK / NACK return. In this example, there are four possible MA signatures that can be used by a UE to send uplink transmissions without concession, which are indexed using values m = 1, ... 4. There are also four possible time-frequency regions that can be used by the UE to send the uplink transmission without concession, which are indexed using values n = 1, ... 4. The combination of the MA signature used by the UE (m) and the region without concession used by the UE (n) maps to a specific orthogonal code and location of the frequency frequency on the dedicated downlink recognition channel. For example, if UE 102a uses the MA signature identified by the index value m = 3 and UE 102a sends its uplink transmission without concession using the region of non-concession resources identified by the index value n = 1, then the UE knows from table 420 that the orthogonal sequence used for its ACK / NACK return on the dedicated downlink recognition channel is the C orthogonal sequence, and the temperature frequency location of its ACK / NACK return on the recognition channel
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38/156 dedicated downlink is time frequency location i.
[0076] The orthogonal sequence and the location of the frequency frequency in the dedicated downlink recognition channel can also be identified by an index. For example, in table 420, each (m, n) maps to a particular (x, y) where x identifies the orthogonal sequence and x is A, B, C or D, and where y identifies the location of the frequency frequency and y is i, ii, iii or iv. X can be referred to as the orthogonal sequence index, and y can be referred to as the resource group index (or PHICH type resource group index). The index is used by the UE to derive the orthogonal sequence to be used to decode the return and the time-frequency location of the return.
[0077] Therefore, in operation, the UE can perform the following operations to receive and decode its return from ACK / NACK to an uplink transmission without a concession sent by the UE. The UE first determines which subframe or TTI the downlink recognition channel that carries its return is located based on the subframe or TTI used by the UE to send the uplink transmission without a concession (i.e., the w + k mentioned above) . The UE then maps the combination of its used MA signature (m) and region without concession used (n) to index (x, y), for example, as in table 420 of Figure 7. index (x, y) informs the UE of which orthogonal sequence to use to decode the return and the time-frequency location of the return in the dedicated downlink recognition channel.
[0078] Table 420 in Figure 7 is just an example. In
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39/156 some modalities, a combination of m and n is necessary to determine only the orthogonal sequence used for the ACK / NACK return and the time-frequency location of the ACK / NACK return. In other modalities, as in table 420 in Figure 7, the value m maps only the orthogonal sequence used for the ACK / NACK return and the value n maps only the time-frequency location of the ACK / NACK return, or vice versa. versa. In some modalities, there may be only one region with no possible concession that can be used by the UEs in a given TTI, subframe or frame, in which case n is always equal to 1, and the MA m signature index can be mapped only to a combination of orthogonal sequence and the time-frequency location on the dedicated downlink recognition channel.
[0079] In some embodiments, the MA m signature index is a reference signal index. In other embodiments, the MA signature index m maps to a combination of reference signal index and MA coding / signature / spreading table used. In some modalities, the index of region of access without concession n can be represented by the first or last index of physical resources block (PRB).
[0080] In some modalities, O index in sign of reference can be mapped to O index in sequence orthogonal, and the combination of index in region without concession
and MA coding / signature / spreading table index can be mapped to the resource group index or the time-frequency location of the dedicated DL recognition channel.
[0081] In some ways, if the EU identity can
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40/156 be determined by activity detection (for example, the MA signature uniquely identifies the UE in the uplink resources without concession), then an index of UE m can be used in place of the signature index of MA m. The UE index m can be an identifier uniquely associated with a UE for the non-grant access region. For example, if only 25 UEs can access uplink resources without concession, then each of the 25 UEs can be assigned a respective EU index between 1 and 25. The UE index is known to both the UE and the base station. . The EU index can be predefined or semi-statically configured. The UE index can be assigned as part of the radio resource control (RRC) signaling. If UEs can only access one uplink region without concession in the given frame, subframe or TTI, then each UE index can be mapped to a unique index value (x, y). If UEs can access multiple regions without concession in the given frame, subframe or TTI, then the UE index together with the region without concession index together can be mapped to a single index value (x, y).
[0082] In some embodiments, the return sent on the dedicated downlink recognition channel for an uplink transmission without concession can be two bits (for example, using QPSK). One of the bits can be used to indicate whether the activity detection was successful, and the other of the bits can be used to indicate whether the data decoding was successful. In some embodiments, the two bits can be sent on different resources on the downlink recognition channel
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41/156 or using different orthogonal sequences. For example, an uplink transmission without a concession having a particular (m, n) can be mapped to two index values (x, y), where each of the two index values (x, y) corresponds to a respective location orthogonal sequence / resource file carrying one of the two return bits.
[0083] The possible benefits of the modalities that use the dedicated downlink recognition channel (for example, a PHICH type channel) are as follows. Only one return bit is sent before encoding ('1' = ACK, '0' = NACK or vice versa), which means possible savings in overhead. In addition, there is no need to completely identify the UE, for example, there is no need to identify the UE (Temporary Radio Network Identifier) RNTI, to send an ACK / NACK. Instead, the base station only needs to perform successful activity detection to obtain the MA signature (index m). The base station would know the uplink resources used (index n) for uplink transmission without concession based on the time-frequency location in which the uplink transmission was received. The possible disadvantages of the modalities that use the dedicated downlink recognition channel (for example, a PHICH type channel) are as follows. It may be more difficult to add additional information at the top of the 1-bit ACK / NACK feedback, the method can only work well for synchronous feedback, and reliability can be reduced due to not using a CRC.
[0084] Figure 8 is a method performed by the base station
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100 and EU 102a, according to an embodiment. In step 422, UE 102a transmits a non-leased uplink transmission to base station 100 in non-leased uplink resources. Uplink transmission without a concession uses an MA subscription. In step 424, the base station 100 receives the uplink transmission without concession. In step 426, the base station performs activity detection to obtain the MA signature and then attempts to decode the data on the uplink transmission without concession. In step 428, base station 100 transmits, on a downlink acknowledgment channel, feedback related to uplink transmission without concession comprising an ACK or a NACK. An orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signatures and the uplink resources without concession. In step 430, the ACK or NACK is received by UE 102a on the downlink acknowledgment channel.
Another Option - Return of individual ACK / NACK [0085] In some embodiments, base station 100 can transmit ACKs or NACKs for uplink transmissions without concession for each individual UE. In some embodiments, the ACK / NACK return to an individual UE can be transmitted via downlink control (DCI) information. Multiple DCIs would be transmitted separately when the ACK / NACK return was being transmitted to multiple UEs, that is, each UE would have its own individual DCI.
[0086] For example, the ACK or NACK for a particular UE
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43/156 can be included in the DCI for that UE that has a CRC field that is masked with the UE ID. The UE ID can be the RNTI for the UE (for example, the cell RNTI (C_RNTI)), although this is not a necessity. If the UE ID is the RNTI for the UE, then the RNTI can be signaled through the RRC channel. The DCI can be transmitted at a location within the search space defined by the UE ID (for example, defined by the C_RNTI). By monitoring the potential DCI command, the UE may attempt to decode all possible locations of DCIs within its research space. If the CRC checks with the assigned UE ID, then the control channel is declared as valid and the UE processes the information within the DCI.
[0087] In some embodiments, the RNTI used for the retransmission of a transmission without a concession and the RNTI used for transmission based on the concession or retransmission of a transmission based on the concession are different. We can call the RNTI used for transmission without concession as RNTI without concession (GF-RNTI) or C-RNTI without concession (GF C-RNTI), and the RNTI used for concession-based transmission as C-RNTI based on concession (GB CRNTI ). For example, GB C-RNTI can be used to at least mask the CRC of a PDCCH used for a staggering concession for concession-based transmission. The GF CRNTI can be configured in EU-specific RRC signaling. GB C-RNTI can be configured in EU-specific RRC signaling or other EU-specific signaling.
[0088] The search space location in the control channel (DCI) can be defined for UEs operating in non-concession mode. In some modalities, the location of the research space can be indicated by the CCE index
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44/156 potentials (control channel elements) in each subframe / TTI. The index can have a predefined relationship derived from the UE ID without concession (such as C_RNTI) or the group ID without concession (such as a group_RNTI) assigned to the UE. The EU ID without concession used to define the search space for the PDCCH can be the GF C-RNTI or the GB C-RNTI. This method is similar to the definition of PDCCH search space in LTE.
[0089] Another way to determine the search space is to explicitly flag DCI's search space locations. The format provided can be a time-frequency region, within which the UE without a concession must search for all CCEs. This explicit signaling can be performed on RRC signaling. This is similar to the ePDCCH search space defined in LTE, for example, defined in ePDCCH_Config in RRC signaling. In one embodiment, if an ACK / NACK is to be sent to UE 102a, then ACK / NACK is included in the DCI for UE 102a. Encoder 210 at base station 100 masks at least part of the DCI with UE ID from UE 102a. Masking may involve modifying at least part of the information in the DCI using UE ID from UE 102a. As an example, the DCI CRC can be masked by shuffling the CRC with the UE ID of UE 102a. The location on the downlink control channel, where UE 102a searches for its DCI, can be known to UE 102a based on UE ID 102a or based on the non-concession uplink resources used by UE 102a to send the uplink transmission without concession. UE 102a searches for the appropriate area of the downlink control channel by its DCI. Assuming that UE 102a does not know
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45/156 the exact time-frequency partition that carries its control information, then the decoder 218 of UE 102a blindly decodes the control information in its research area and attempts to unscramble the CRC using UE ID 102a. An incorrect CRC is interpreted by UE 102a as an indication that that particular control information on the downlink control channel is not intended for UE 102a. A correct CRC indicates to UE 102a that its DCI has been correctly decoded. UE 102a can then retrieve the ACK or NACK from the decoded DCI. The UE ID may be in the DCI payload. The UE ID can be an RNTI or an upper layer ID, the upper layer ID does not need to be linked to a specific cell and known to the base station and the UE.
[0090] The DCI decoded by UE 102a can have different formats and can include different information. As an example, DCI may include a lease for a retransmission, indicating to UE 102a that the base station did not successfully decode the uplink transmission without an initial lease. In such cases, a NACK may not be explicitly included in the DCI, as a NACK is implied by virtue of the fact that the DCI includes a concession for a retransmission. The concession may change the transmission without a concession to a concession-based retransmission.
[0091] In some modalities, the DCI has a relatively simple format, for example, it does not include information for a concession. As an example, DCI can be a little simple: '0' for ACK and '1' for NACK, or vice versa. In some embodiments, the DCI may include the identity of the UE if an ACK is being sent to the UE, or the DCI may contain
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46/156 the UE ID or (if the UE ID is not known to the base station) the corresponding MA signature index for the MA signature on the uplink transmission if a NACK is being sent to the UE. In some embodiments, a particular UE may have several uplink transmissions without concession, in which case there may be several HARQ processes.
[0092] In some embodiments, the DCI or the individual return channel carrying the ACK / NACK may also or instead include the HARQ process ID (or HARQ process number) for the package being ACK'd / NACK'd. The ACK / NACK can contain an HARQ process number (or HARQ process ID or any attribute that identifies the HARQ process number or transport block index (TB), for example, MA signature index or index access region without concession or combination of the two) explicitly or implicitly, which is used to identify which TB the ACK / NACK is used for if there are multiple TBs transmitted. The HARQ process ID can be implicitly or explicitly signaled to the base station in the uplink transmission without concession. An example of implicit signaling is whether the HARQ process ID is identifiable for the base station based on the MA signature used by the UE. The MA signature can be a reference signal or a coding / signature / sequence table or used for a multiple access (MA) scheme or any other attribute described above. For example, if an MA scheme uses two different coding tables to transmit two TBs (corresponding to two HARQ processes). The base station identifies the coding table by detecting
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47/156 of activity. The base station can then indicate the codebook index or the corresponding HARQ process index in the ACK / NACK, which identifies the TB for which the ACK / NACK is intended. In some embodiments, the HARQ process ID can be identified implicitly through different regions of access without concession. For example, if a UE is configured to be able to access two access regions without concession in a period of time. The UE can transmit two TBs that correspond to two different HARQ processes. In the ACK / NACK return, the grant access region index or the HARQ process ID can be indicated implicitly or explicitly, such that the UE can identify which TB the ACK / NACK return is destined for. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID. The HARQ ID can be more robustly protected, so that the base station can identify it, even if it cannot successfully decode the data.
[0093] In some embodiments, the individual DCI can be transmitted together with other information to the UE, for example, additional data to be transmitted to the UE or a concession to send a retransmission of a current or new transport block (TB) transmission of a new TB.
[0094] In general, the DCI used to return HARQ (ACK / NACK or concession) in relation to a transmission without concession can be associated with the GF C-RNTI or GB C-RNTI. In some embodiments, the UE ID used for the DCI used to grant a retransmission of an initial transmission without a concession is the GF C-RNTI. In some other
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48/156 modalities, the UE ID used for the DCI used to grant a retransmission of an initial transmission without concession is GB C-RNTI. The GF C-RNTI is used at least to mask the CRC of the DCI used for retransmission of the initial transmission without concession. If DCI is used for retransmission it can be identified by a new data indicator field (NDI) in the DCI. The NDI can be a 1-bit field, which can be 0 or 1. If the UE detects a DCI lease with a CRC masked by GB C-RNTI, the UE may consider granting a retransmission lease if the NDI is not switched in relation to the last concession of the same HARQ process. On the other hand, if there is a DCI concession with a CRC masked by GB C-RNTI, and the NDI is alternated with respect to the last concession of the same HARQ process, the UE may consider the concession a staggering concession for a new TB . In transmission without concession, there is no staggering concession for the initial transmission without concession. Whether the DCI concession is for retransmission is determined by the fixed value of the NDI field in the concession. For example, if after the initial transmission without a concession, the UE detects a DCI with CRC masked by GF C-RNTI and the NDI field in the DCI is equal to 1, the UE may consider the DCI as a relay concession of the initial transmission without concession. Which TB the retransmission is for can be identified by the UE using the HARQ process ID included in the DCI. Note that there may be a configured or predefined mapping between non-grant resources and the HARQ process ID, so that the UE knows which TB the HARQ ID corresponds to. On the other hand, if the UE detects a DCI with CRC masked by GF CRNTI and the NDI field in the DCI is equal to 0, the UE can consider
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49/156 to DCI as an ACK of the transmission without concession. Which TB of the non-concession transmission the ACK corresponds to can be identified by the HARQ process ID or number included in the DCI. Note that, in some modalities, there is no explicit ACK / NACK bit in the DCI. The UE can consider the DCI as a TB ACK associated with the HARQ process ID in the DCI if the DCI is associated with the GF C-RNTI and NDI = 0. In some modalities, if the UE detects a DCI with GF masked CRC C-RNTI, the UE can consider it as a retransmission concession of the corresponding HARQ process regardless of the NDI value, ie NDI here is not used to determine whether the concession is a retransmission concession. In some modalities, the DCI used to indicate a TB ACK without a concession may mask the CRC with the GB C-RNTI. If the UE detects a DCI associated with the GB CRNTI and the previous TB transmission with the same HARQ process (identified by the HARQ process ID in the DCI) is a non-grant transmission, the UE may consider the DCI as a TB ACK no grant associated with the HARQ process ID regardless of the NDI value. In some other modalities, the UE considers only the DCI associated with GB CRNTI an ACK of the transmission without concession if NDI = 0. If the DCI associated with GB C-RNTI is used to indicate an ACK, the UE can also consider it as including an escalation grant for a new TB with the included HARQ process ID. If the UE has data to transmit, the UE can transmit a new TB using the resource configured in the DCI associated with the GB C-RNTI. In some embodiments, if the DCI associated with GF C-RNTI is used to indicate an ACK, the UE may not regard it as a grant of
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50/156 staggering a new TB and may not transmit a new TB based on the concession. In some other embodiments, if the DCI associated with GF C-RNTI is used to indicate an ACK, the UE may also consider it to include a scaling grant for a new TB with the included HARQ process ID. If the UE has data to transmit, the UE can transmit a new TB using the resource configured in the DCI associated with the GF C-RNTI.
[0095] The sending of individual DCI normally requires the base station to determine only the identity of the UE. In some embodiments, the base station can obtain the UE ID by decoding the data on the uplink transmission without concession. In modalities in which, for a given uplink resource region without concession, the MA signature uniquely identifies the UE, then detection of the MA signature by the base station allows the base station to uniquely identify the UE. The base station can then obtain the UE ID for the UE, for example, using a mapping between the MA signature and the UE ID.
[0096] In some modalities, DCI can be used to terminate a continuous repetition / retransmission. In some embodiments, the DCI format may be similar to a current DCI format, such as the DCI 0 format in LTE for uplink scheduling. The HARQ-ACK message can be implicitly implied. For example, the DCI format that transmits a HARQ-ACK for termination of a continuous retry / retransmission may be similar to the DCI format used for LTE semi-persistent scaling release (SPS) validation. In some modalities, DCI can be a new format that is
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51/156 used for ACK / NACK without a full concession.
[0097] In some embodiments, DCI may contain a staggering concession for a retransmission that switches the transmission without concession to a concession-based retransmission. In some embodiments, the DCI may contain a staggering concession for a new UE transmission that switches the new UE package without a concession to a concession-based transmission. The explicit grant may implicitly imply a NACK return.
[0098] In some modalities, the DCI may contain a staggering concession for the transmission of a new TB, in which case, it may implicitly imply an ACK of a previous TB.
[0099] In some modalities, the return channel can be transmitted through a control channel or data channel (and may not be in DCI format). The time-frequency location of the return channel can have a fixed relationship with the time interval or subframe number or with the transmission resource without concession or with the combination of transmission resource without concession and MA subscription used. The content within the return channel can be the UE ID being recognized or any content previously described for the individual DCI.
[00100] In some embodiments, the location of the ACK / NACK for a UE in the individual DCI may have a fixed timing relationship with the uplink resources without concession used to send the uplink transmission without concession being ACK'd / NACK 'd. For example, if a UE sends uplink transmissions without concession in the subframe (or TTI) w, then the ACK / NACK for that
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52/156 uplink transmission without concession is sent in the DCI of the subframe (or TTI) w + k. However, in some modalities, ACK / NACK may not necessarily have a fixed timing relationship with resources without a concession. In modalities where the HARQ process ID or any similar indication is included in the individual DCI for a UE, then the UE may be able to identify which transport block (or package) is recognized by using the HARQ process ID in instead of DCI timing. In some modalities, the ACK / NACK sent in the individual DCI can be used to terminate a continuous repetition. In this case, individual support of the DCI transmitted at an arbitrary time can be beneficial.
[00101] Finally, as mentioned earlier in some modalities, the individual ACK / NACK for a UE does not need to be sent in DCI. Instead, for example, an ACK / NACK for a UE can be sent on a data channel, for example, a PDSCH. The ACK / NACK location on the data channel can be sent to the DCI. The DCI indicating the location of the ACK / NACK can still be scrambled by the UE ID in some modalities. The HARQ return can be an EU-specific DCI with CRC masked by the GF C-RNTI. The DCI may contain a scheduling concession that schedules a PDSCH transmission. The actual HARQ or ACK / NACK return content can be transmitted on that data channel (PDSCH).
[00102] In some modalities, the individual ACK / NACK can be sent on a return channel at a time-frequency location that has a fixed mapping relationship with the combination of or one of the non-concession region index and subscription index of MA. In this scenario, the UE knows where
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53/156 look for the return. The return content may be similar to the case of sending ACK / NACK to the DCI, but it may not be in a DCI format. It may contain a CRC, but the CRC may or may not be masked by the UE ID.
[00103] In some modalities, the individual ACK / NACK channel may contain at least one or some of, but not limited to:
[00104] The index of signature of MA identified by by detecting activity or an combination of the index in signature of MA and the index in region of access without concession. [00105] A UE ID, if the UE is identified. [00106] A number of HARQ process that identifies The which TB the return corresponds. At times one attribute that identifies the number of process in HARQ (for example, one index of signature from MA, one index of ; table in coding that identifies the number of process HARQ) is
included instead. Sometimes, the HARQ process number may not be explicitly included, but it can be derived from other attributes. The advanced timing signal (TA) or timing information used to adjust the uplink timing for uplink synchronization if TA is estimated in transmission without an initial concession (for example, using a preamble or an RS for estimating TA).
[00107] A temporary identity, for example, a TCRNTI similar to that assigned in an LTE RAR message, used for additional communications between the UE and the network.
[00108] A staggering concession, indicating the resource, including time-frequency resource, MCS, signal
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54/156 reference, MA signature, etc., which the UE will use for the following transmissions or retransmissions.
[00109] Feature hop pattern or RV hop pattern, or MA signature hop pattern for the following transmissions / retransmissions.
[00110] An explicit or implicit signal to indicate whether it is ACK or NACK and, optionally, a signal to indicate whether the activity detection successfully detects the MA signature.
[00111] Figure 9 illustrates a method performed by base station 100 and UE 102a, according to another modality. In step 423, UE 102a transmits a non-leased uplink transmission to base station 100 in non-leased uplink resources. Uplink transmission without a concession uses an MA subscription. In step 425, the base station 100 receives the uplink transmission without concession. In step 427, the base station performs activity detection to obtain the MA signature and then attempts to decode data on the uplink transmission without concession. If the data is decoded, then base station 100 can obtain the UE ID (e.g., RNTI) from the UE 102a. In step 429, the base station 100 transmits, in individual downlink control information, feedback relative to the uplink transmission without concession comprising an ACK or a NACK. If an ACK is sent, base station 100 masks the return using the UE ID, for example, scrambling the return CRC with the UE ID. If a NACK is sent, base station 100 only masks the return using the UE ID if the UE ID is known to the base station, for example, if the subscription to
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MA uniquely identifies UE 102a in uplink resources without concession. In step 431, the ACK or NACK is received by the UE 102a, for example, if the CRC is shuffled with the UE ID 102a, then the UE 102a receives the ACK or NACK for unscrambling the CRC using the UE ID 102a.
Another option - ACK / NACK on the data channel [00112] In some modalities, the ACKs / NACKs are transmitted by the base station on a downlink data channel, for example, on a physical downlink shared channel (PDSCH). A UE that sent an uplink transmission without a concession searches for DCI that indicates where, in the data channel, the ACK / NACK can be found. The DCI can be an individual DCI, as above, in which case the DCI can be masked using the UE ID (for example, GF C-RNTI). Alternatively, base station 100 can transmit ACKs / NACKs to multiple UEs on the same resource partition as the downlink data channel. Each UE that sent an uplink transmission without concession to either ACK / NACK looks for the same DCI, which indicates the location of the resource partition having the ACKs / NACKs. The DCI may contain a scheduling concession that schedules a downlink transmission over a data channel (for example, a PDSCH). The actual HARQ or ACK / NACK return content can be transmitted on that data channel (PDSCH). The same DCI means that it can be a common DCI for the group, as described later in the disclosure. DCI can be masked using a common ID value, for example, a common RNTI, such as GF_Common_RNTI. The common ID value is known for each UE that sends an uplink transmission without a concession and is used for
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56/156 decode the DCI. The common ID value can be predefined or indicated using the RRC signal. The common ID can be the same group RNTI (for example, GF_group_RNTI), as described later in the group ACK / NACK of this disclosure.
[00113] The search space for DCI on the downlink control channel can be based on the uplink resources without concession used.
[00114] As an example, ten UEs are configured to be able to send any uplink transmission without concession that they may have in a first set of uplink resources without concession. The ten UEs are informed of the GF_Common_RNTI for the first set of uplink resources without concession. The ten UEs know how to search a particular area of the downlink control channel based on the location of the first set of uplink resources without concession. Each of the ten UEs uses GF_Common_RNTI to decode the DCI. The DCI indicates where, in the downlink data channel, the ACKs / NACKs for the ten UEs are located.
[00115] When ACKs / NACKs for multiple UEs are located on a common resource partition on the downlink data channel, for example, as in the example in the paragraph above, then each ACK / NACK is associated with information identifying the UE to which the ACK / NACK belongs. The information can be the UE ID, or an index identifying the MA signature transmitted in the uplink transmission without concession. In some modalities, there may also be additional information associated with an ACK / NACK. For example, a NACK for a particular UE may have a concession
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57/156 associated with him who schedules a concession for a retransmission. Or the NACK may indicate to the UE that any retransmission must be performed using an uplink transmission without concession, possibly using a specific hop pattern or RV hop pattern, or MA signature hop pattern.
Another option - Group ACK / NACK [00116] In some embodiments, a single ACK / NACK payload can recognize more than one UE. Such an ACK / NACK will be referred to as a group ACK / NACK.
[00117] UEs are divided into different groups by the base station. The pool can be based on which UEs are most likely to access the same time-frequency uplink resources without concession. In some modalities, there may be only one group, for example, when there are only a small number of UEs that can send uplink transmissions without concession. Groups can be updated over time. Each group has a respective group ID, for example, GF_group_RNTI, which distinguishes the group from other groups. In modalities where there is only one group, the group ID may be predefined, or it may not be necessary. In some embodiments, the group ID GF_group_RNTI may not be explicitly flagged for the UE. The GF_group_RNTI can be predefined as a function of at least one of the subframe or time slot number and frame number and known to both the UE and the base station. In some modalities, each region of access without concession can have its own group ID, which can be known in advance. The region of non-concession access can refer to time-frequency resources that
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58/156 the UE can access to carry out the transmission without concession. Different regions of resource without concession may refer to different time-frequency locations. Different frequency locations may refer to different frequency partitions, different bands or sub-bands, different carriers or subcarriers, different parts of bandwidth (BWP), different resource blocks (RBs) or groups of resource blocks ( RBGs) or in general any different frequency unit or different frequency regions assigned to the UE. Each UE in each group is assigned a position index, for example, GF_ack_index. The position index identifies the UE from other UEs in the group. For example, if there are four UEs in a group, then one UE can receive a position index of '1', another UE receives a position index of '2', another UE receives a position index of '3' and the remaining UE is assigned position index '4'. In some embodiments, the UE position index can be configured semi-statically, for example, in RRC signaling.
[00118] In some embodiments, upper layer signaling (such as RRC signaling) is used to assign UEs to groups, signal the group ID for each group, and assign a position index to each UE in each group. In some modalities, RRC signaling can also indicate for each UE how many other UEs are in the same group.
[00119] In some embodiments, the EU position index can be replaced by a combination of non-grant access region index (sometimes the index is only for the index within a time frame or subframe) and signature index of MA, in which case the UE index may
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59/156 does not need to be signaled to the UE in advance, since the UE will know its index based on the MA subscription it uses and the non-concession resources it uses to send the uplink transmission without concession. In some modalities, the index of region of access without concession may be an index of different frequency partitions, different bands or sub-bands, different carriers or subcarriers, different parts of bandwidth (BWP), different blocks of resources (RBs) ) or resource block groups (RGGs) or in the general index of different frequency unit or frequency regions assigned to the UE.
[00120] Once the groups are configured, a group ACK / NACK is used for each group for recognition or negative recognition of uplink transmissions without concession to UEs in that group. In some embodiments, the group ACK / NACK can ACK all incoming packets that are successfully decoded into a TTI or a time frame or subframe.
[00121] In some embodiments, the group ACK / NACK is sent on a downlink control channel that is common to multiple UEs or addressed to a group of UEs. In such modalities, it can be said that the group ACK / NACK can be said to be sent via a DCI common to the group.
[00122] In some modalities, the DCI common to the group is sent in one of the research spaces defined by the group ID (GF_group_RNTI). The definition of the research space is similar to the individual DCI. In some modalities, the DCI research space common to the group may be among the common research spaces of the link control channel
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Descending 60/156. In some scenarios, the search space can be fixed for a DCI common to the group, so that no blind detection is necessary. By monitoring the potential DCI command, the UE may attempt to decode all possible locations of DCIs within its research space. If the CRC checks with the assigned or derived group RNTI (GF_group_RNTI), the control channel is declared valid and the UE processes the information within the DCI common to the group to obtain the group ACK / NACK.
[00123] In some modalities, the location of the group ACK / NACK is based on the location of the frequency-frequency resources used to send the uplink transmissions without concession. There can be multiple group ACK / NACKs for each time slot (the time slot can mean a time slot, a subframe, a TTi or a general time unit) with each group defined for each resource without concession. For example, each time slot can contain 5 access regions without concession at different frequency locations, so all UEs that access the same access region without concession can form a group. In this case, the group ID (GF_group_RNTI) and the EU position index may not need to be pre-configured or flagged in advance. Each group can have a predefined group ID (for example, GF_group_RNTI) which is a function of non-grant access region resources as well as the time slot index and frame number and known to both the UE and the base station. In other words, the group ID (GF_group_RNTI) can be derived as a function of the time unit, as well as frequency locations of transmission resources without
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61/156 concession used for transmission without concession. In one example, there can be 5 groups without concession with 5 different GF_group_RNTIs corresponding to the 5 different regions of access without concession within the time interval. In this case, gNB can send 5 separate group ACK / NACK via the group DCI which is configured by its corresponding group ID (GF_group_RNTI). The group DCI can be sent in a search space defined by the corresponding group RNTI and the CRC for the group DCI can be masked by the same group ID (GF_group_RNTI). If a group of UEs send uplink broadcasts without concession at time-frequency location A, then search space B in the DCI is searched using the group ID associated with the non-concession access regions (resources) to obtain the ACK / Group NACK for these uplink transmissions without concession. In some modalities, the DCI research space B can be a common research space to send a common DCI to the group, which may or may not depend on the group ID. Each UE that sent an uplink transmission without a concession in the UE group blindly decodes the control information in search area B and attempts to unscramble the CRC using the group ID associated with the non-concession resources. An incorrect CRC is interpreted by the UE as an indication that that particular control information on the downlink control channel is not the group ACK / NACK. A correct CRC indicates to the UE that its DCI has been correctly decoded. UE 102a can then retrieve the group ACK / NACK from the decoded DCI. In some modalities, blind detection may not be necessary, for example instead of research area B, the time resources
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62/156 frequency used to send the map of uplink transmissions without concession to a specific known frequency frequency location in the DCI to decode the group ACK / NACK. In some embodiments, the group ID is not used to scramble the DCI CRC.
[00124] As a more specific example of the group ID (group RNTI) as a function of the time unit or frequency locations of transmission resources without concession will now be explained. The group ID can be a function of a time resource index and a frequency resource index, for example
GF_group_RNTI = f (t_index, f_index) [00125] As a more specific example
GF_group_RNTI = A * t_index + B * f_index + C; where A, B, C are constants and * represents multiplication.
[00126] The index information / frequency resource information f_index can include at least one of an index of different frequency partitions (for example, frequency partition index), different bands or sub-bands (for example, index of frequency) band or subband), different carriers or subcarriers (for example, carrier index or subcarrier index), different parts of bandwidth (BWP) (for example, BWP index), different resource blocks (RBs), or resource block groups (RBGs) (for example, RB index or RBG index) or in general index of different frequency units or different frequency regions (for example, frequency unit index or frequency region index) .
[00127] The time resource index / information (t_index) can include at least one of a system frame index,
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63/156 a subframe index, a range index, a mini-range index, a symbol index. The non-grant resource information that is used to calculate the group ID can be configured for the UE via broadcast signaling, RRC signaling, DCI signaling or any combination of the above through the non-grant resource configuration. In the example above, there are 5 groups without concession with 5 different GF_group_RNTIs corresponding to the 5 different regions of access without concession within the time interval. The 5 non-concession access regions can be 5 different frequency partitions, the frequency partition can be 5 sub-bands, each containing a sub-band index or simply frequency partition index known to the UE by the resource partition without concession. Each UE and base station can derive the same group RNTI as a function of the time index (for example, the interval index) and the frequency location index (for example, the frequency partition index or subband) . UEs that are accessing the same frequency partition (or the same access region without concession) then share the same group RNTI or group ID. The derived group ID is then used to mask the CRC of the group ACK / NACK, which can be transmitted in the DCI common to the group. If the base station sends a DCI common to the group for each group, then there may be five different DCIs common to the group for the same interval. In some embodiments, the frequency location index can be an RB index. However, if multiple RBs are used / defined for transmission without concession, the frequency index used to calculate the group ID can be the initial or final RB index.
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64/156 [00128] In some embodiments, if a separate group ID and group ACK / NACK are used for different access regions without concession in a time interval, then the UE position index used in the ACK / NACK of group can have a predefined mapping relationship with the MA subscription index.
[00129] In some modalities, all UEs that access resource regions without concession in a time interval are sent back using a group ACK / NACK return. A GF_group_RNTI group ID is defined for the group ACK / NACK return. The GF_group_RNTI can be similarly defined as RA-RNTI defined for random access in LTE. In some embodiments, the group ID (GF_group_RNTI) and the UE position index associated with the group can be flagged for the UE in advance (for example, in the RRC as described above). In some other embodiments, the group ID (GF_group_RNTI) can be predefined and known to all UEs without concession and the base station 100. The GF_group_RNTI can be a function of the time slot number and frame number, but still known as both the UEs without concession and the base station 100. In this scenario, the group ACK / NACK can be sent in a DCI common to the group configured by this GF_group_RNTI. The DCI can be sent in a research space defined by GF_group_RNTI and with a CRC masked by GF_group_RNTI. Since the group ACK / NACK may contain ACK / NACK feedback for UEs accessing multiple access regions without concession for the time interval, the UE position index, if not configured in advance, may have a predefined mapping with the combination of access region index
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65/156 without concession and MA subscription index. The access region index without concession can be any frequency location index, such as band or subband index, RB or RBG index, BWP index, carrier or subcarrier index, frequency partition index, etc.
[00130] In some embodiments, the group ACK / NACK can be a message having k fields (for example, k bits), where each field is associated with a certain index of UE position and provides an indication of whether the transmission uplink without granting that UE is recognized. As an example, a group can have k UEs and the group ACK / NACK can be a word with k bits. Each bit in the word maps to a respective of the k UEs. An example is illustrated in Figure 10 at 434. A bit value of '1' means that an uplink transmission without concession from the corresponding UE has been successfully received and decoded, i.e. an ACK. A bit value of '0' means NACK. If there is no ACK or NACK for a particular UE, then the bit corresponding to that UE is set to '0'. Therefore, if a UE in the group sends an uplink transmission without a concession and its position index in word 434 is '0', then that UE does not know whether the activity detection was successful.
[00131] In some embodiments, the UE position index is pre-configured for the defined group (GF_group_RNTI) in the upper layer signaling (for example, RRC signaling), as described previously. In some embodiments, the EU position index has a predefined mapping with the combination of the non-grant access region index and MA subscription index and known as
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66/156 both the UEs and gNB.
[00132] Figure 11 illustrates a variation of Figure 10 in which two bits bl and b2 are associated with each index position of UE in word 436. Bit bl indicates whether or not the activity detection was successful for the UE (for example, '1' = 'yes') and bit b2 indicates whether or not the data was successfully decoded (for example, '1' = 'data successfully decoded'). The UE can use the additional information to decide what to do next. For example, if the word 436 indicates that the activity detection was not even successful for the UE, then the UE can resend the same initial transmission with the same RV, whereas if the word 436 indicates that the activity detection was successful, but the data was not successfully decoded to the UE, so the UE can send a retransmission using another VR (for example, a higher VR).
[00133] In Figures 10 and 11, the UE position index can be based on an MA subscription index, or a combination of an MA subscription index and an index indicating which uplink resources without concession were used to send the uplink transmission without concession.
[00134] In some embodiments, a particular UE may have several uplink transmissions without concession, in which case there may be several HARQ processes, each HARQ process may indicate a TB. The HARQ process ID can be implicitly or explicitly signaled to the base station in the uplink transmission without concession. An example of implicit signaling is whether the HARQ process ID is identifiable to the base station based on the signature of
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MA used by the UE. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID.
[00135] The position index may additionally include the HARQ process ID. Figure 12 illustrates an example of a group ACK / NACK which is the same as in Figure 11, but each HARQ process ID in each UE has its own set of bits bl and b2. There are N different HARQ process IDs possible for a UE. The UE knows where to look in
word 438 based in your index in position and in your ID of process of HARQ. [00136] In others modalities, one EU can to be assigned to multiple indexes position, for example, if the UE it is using multiple subscriptions in MA or if the UE has multiple HARQ process IDs. 0 EU knows what index of
position is associated with the signature of a particular MA or particular HARQ process ID corresponding to the uplink transmission without concession of the UE.
[00137] In some embodiments, the group ACK / NACK includes the UE ID for each UE that the group ACK / NACK is recognizing. In some modalities, the presence of the UE ID in the group ACK indicates to the UE that its uplink transmission without concession was successfully received and decoded by the base station. The absence of the UE ID indicates to the UE that its uplink transmission without concession was not successfully decoded by the base station, that is, an implicit NACK. In some modalities, instead of including the UE ID, the group ACK includes, for each uplink transmission without concession being recognized, an index corresponding to the MA subscription and link resource
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68/156 ascending without concession that was used.
[00138] Figure 13 illustrates a group 440 ACK / NACK, according to another modality. Group 440 ACK / NACK includes a 442 field indicating the number of UEs being ACK'd or NACK'd in group 440 ACK / NACK. Another 444 field indicates the length of each UE ID. Another field 446 indicates whether the UEs identified in group 440 ACK / NACK are being ACK'd or NACK'd (for example, '1' = ACK and '0' = NACK). The UE ID of each UE being ACK'd or NACK'd is then present in field 448. The group ACK / NACK is encoded as a payload and a CRC 450 is added. If the 440 group ACK / NACK is sent via the DCI common to the group, the CRC 450 can be shuffled by a group ID that is known to both the UE and the base station.
[00139] Fields 442, 444 and 446 are optional. None or only some of the fields 442, 444 and 446 are included in the implementation dependency. For example, field 444 can be omitted if the UE ID always has a fixed length known in advance to the UEs and base station, for example, a fixed length UE ID obtained through activity detection and data decoding. As another example, field 446 can be omitted if the presence of a UE ID always means that the UE is being ACK'd. In addition, in some modalities, the CRC 450 may not be present. In addition, in some embodiments, each UE ID of some or all of the UE IDs in field 448 can be replaced by: (i) an index identifying the MA signature used by the UE that sends the uplink transmission without concession being ACK 'd / NACK'd; or (ii) a combination of an index identifying the MA signature used by the UE and
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69/156 another index identifying the uplink resources without concession used by the UE.
[00140] In some modalities, two separate group ACK / NACKs having the format of Figure 13 can be transmitted: one group ACK / NACK recognizing transmissions, and another group ACK / NACK recognizing negatively transmissions. In other modalities, a single group ACK / NACK can include ACKs and NACKs. For example, fields 446 and 448 can be present twice: once recognizing transmissions, and again for negative acknowledgment transmissions. In any case, if NACKs are being sent, the base station may not have been able to identify the UEs being NACK'd, in which case a UE ID may be replaced with an u-link transmission MA subscription index being NACK 'd, or a combination of MA subscription index and an index identifying the uplink resource without concession used by the uplink transmission being NACK'd. When there is both an ACK and NACK field, then a UE that has sent an uplink transmission without a concession and does not see an ACK or NACK in the group ACK / NACK knows that detecting activity from its uplink transmission without a concession it was not even successfully executed by the base station.
[00141] A group ACK / NACK that includes the UE ID for each UE being ACK'd / NACK'd (for example, as in Figure 13) can be shorter than a group ACK / NACK comprising a bitmap (for example as in Figures 10 to 12) if there are a large number of UEs that could potentially be ACK'd / NACK'd, but only a small subset of the large
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70/156 number of UEs is actually being ACK'd / NACK'd in the group ACK / NACK.
[00142] For all formats described above (for example, Figures 10 to 13), the group ACK / NACK can be transmitted on a downlink data channel (for example, a PDSCH), in link control information descending (DCI), or on a return channel at a known location that may not be in DCI format.
[00143] In the modalities in which the group ACK / NACK is transmitted in the DCI common to the group, a group ID is predefined or signaled and the DCI is transmitted in the search space defined by the group ID (GF_group_RNTI). GF_group_RNTI can be configured in advance or predefined for a time slot or a region without concession, as previously described. The CRC field in the DCI is also often masked with the group ID. More details of the transmission in the DCI format are described earlier.
[00144] In the modalities in which the group ACK / NACK is transmitted on a shared downlink channel (for example, a PDSCH) instead of in downlink control information (DCI), then the group ACK / NACK it can also have any of the formats discussed above, for example in relation to Figures 10 to 13. In some embodiments, a downlink control channel (for example, PDCCH) can indicate the location of the group ACK / NACK on the shared channel downlink. This indication can have the same format as a staggering concession, but inform the UEs in the group where to look for the group ACK / NACK in the downlink data channel,
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71/156 what modulation was used for the group ACK / NACK, etc. In some modalities, the nomination can be in a DCI format and sent in a search space defined by the group ID (GF_group_RNTI) and with a masked or scrambled CRC using the group ID. In some embodiments, the indication may be at a fixed location on the downlink control channel that is known to the UEs in the group, in which case the UEs in the group need not search for a search area on the downlink control channel using the Group ID.
[00145] In some embodiments, the group ACK / NACK on the downlink data channel may include other information for the UEs in the group, for example, the downlink data to be transmitted to one or more of the UEs in the group.
[00146] In some modalities, the group ACK / NACK can be transmitted in a fixed time-frequency location in relation to the time interval (subframe) or the transmission resources without concession or a combination of the two. The group ACK / NACK can still have any of the formats discussed above, for example, in relation to Figures 10 to
13. The return channel carrying the return information may not necessarily be in DCI. It may not be necessary to have a search space defined by a group ID, and a CRC may or may not need to be masked by the group ID.
[00147] In some modalities, the group ACK / NACK transmitted through the DCI common to the group may have a fixed timing relationship with the timing of the uplink resources without concession used to send uplink transmissions without concession being
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ACK'd / NACK'd, similar to the case of the PHICH type channel. For example, if a group of UEs send uplink transmissions without concession in subframe (or TTI) w, then the group ACK / NACK for that uplink transmission without concession is sent in the DCI of subframe (or TTI) w + k. However, in some modalities, the group ACK / NACK may not necessarily have a fixed timing relationship with resources without concession. In modalities in which the HARQ process ID or any similar indication is included in the DCI, then the UE may be able to identify which transport block (or package) is recognized using the HARQ process ID instead of the DCI timing . In some embodiments, the group ACK / NACK using DCI common to the group can be used to terminate a continuous repetition. In this case, support for DCI transmitted over arbitrary timing can be beneficial.
[00148] In some embodiments, the group ACK / NACK may contain a HARQ process number (or HARQ process ID, or any attributes that identify the HARQ process number or transport block index (TB), for example, MA subscription index or access region index without concession or combination of the two) explicitly or implicitly, which is used to identify which TB the group ACK / NACK is used for if there are multiple TBs transmitted. Some of the formats that include the HARQ ID have been described previously. The HARQ process ID can be implicitly or explicitly signaled to the base station in the uplink transmission without concession. An example of implicit signaling is whether the HARQ process ID is identifiable to the base station based on the signature of
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MA used by the UE. The MA signature can be a reference signal or a coding / signature / sequence table or used for a multiple access (MA) scheme or any other attribute described above. For example, if an MA scheme uses two different coding tables to transmit two TBs (corresponding to two HARQ processes). The base station identifies the coding table by detecting activity. The base station can then indicate the codebook table index or the corresponding HARQ process index in the group ACK / NACK, which identifies the TB for which the group ACK / NACK is intended. In some embodiments, the HARQ process ID can be identified implicitly through different regions of access without concession. For example, if a UE is configured to be able to access two access regions without concession in a period of time. The UE can transmit two TBs that correspond to two different HARQ processes. On group ACK / NACK return, the grant access region index or HARQ process ID can be indicated implicitly or explicitly, such that the UE can identify which TB the group ACK / NACK return to is intended. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID. The HARQ ID can be more robustly protected, so that the base station can identify it, even if it cannot successfully decode the data.
[00149] In some scenarios, the group ACK / NACK may contain only one ACK / NACK for a UE. In this case, all group ACK / NACK signaling methods and formats
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74/156 described in this description may be applicable for individual ACK / NACK when the number of UEs in the group is one or the ACK / NACK targets a UE. For example, if the number of UEs in the group is one, the HARQ return can be sent in an EU-specific DCI, as opposed to a common DCI in the group. The group RNTI can become the GF C-RNTI and is used to mask the DCI for the return of HARQ and can be configured in EU-specific RRC signaling or derived based on transmission resources without concession, for example at least the transmission time and frequency resource without concession. The UE-specific DCI can contain ACK / NACK bits corresponding to each HARQ process, but only for one UE. In this case, the UE-specific DCI may contain a bitmap, with each bit indicating an ACK or NACK for a respective UE HARQ process. The location / position of each bit can have a predefined mapping in relation to a corresponding HARQ process (or HARQ process ID).
[00150] In some embodiments, the group ACK / NACK may comprise a single ACK / NACK payload protected by a CRC. The payload can include an aggregation of all UE IDs or MA signatures corresponding to the uplink transmissions being ACK / NACK'd. Each UE that sent an uplink transmission without a concession then decodes the group ACK / NACK to see if UE ID and corresponding MA signatures can be found in the group ACK / NACK payload and if its uplink transmission without concession was recognized. In some embodiments, a group ACK / NACK can be associated with a time group ID. The group ID can be derived from non-grant resources. For example, if a group of UEs use
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75/156 all uplink resources C to send an uplink transmission respectively without concession, then that group of UEs can be associated with a group ID corresponding to uplink resources C. In some embodiments, there may be a field 1-bit specific indicating that the ACK / NACK is a group ACK / NACK, and the location of the ACK / NACK time and frequency resources is directly linked to the broadcast resources without concession and a group ID may not be necessary. In some modalities, there may be a reserved field (for example, time-frequency location) on the downlink to send a group ACK / NACK. The time-frequency location of the reserved field can be determined based on the location of the uplink resources used for uplink transmissions without concession. For example, if a group of UE each sends its uplink transmission without concession within the time-frequency region A, then the field reserved for the group ACK / NACK may be in the frequency-frequency location B.
[00151] Throughout the group ACK / NACK and individual ACK / NACK described in this disclosure (transmitted on a downlink control channel or downlink shared channel or any return channel in general), there may be additional information transmitted on the return. The return content can be similar to the random access response (RAR) message used for LTE random access. In group ACK / NACK, there can be multiple entries with each entry corresponding to the return to a UE and either indexed by the MA subscription index or includes
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76/156 explicitly the MA subscription index. If the group ACK / NACK corresponds to the return of multiple non-grant access regions, the entry can be indexed by a combination of the non-grant access region index and the MA subscription index. Each entry can contain at least one or a few, but are not limited to:
The. The MA subscription index that is identified by detecting activity or a combination of the MA index
MA signature and of the index in region of access without concession.B. A UE ID, if the UE is identifi cated. ç. A number of process of HARQ that identifies the what TB the return corresponds. At sometimes an attribute what identifies the number of process in HARQ (for example , one MA subscription index, one index of table in
encoding that identifies the HARQ process number) is included instead. Sometimes, the HARQ process number may not be explicitly included, but it can be derived from other attributes.
d. 0 advanced timing signal (TA) or timing information used to adjust uplink timing for uplink synchronization if TA is estimated in transmission without initial concession (for example, using a preamble or RS for TA estimate).
and. A temporary identity, for example, a TC-RNTI similar to that assigned in an LTE RAR message, used for additional communications between the UE and the network.
f. An escalation concession, indicating the resource, including time-frequency resource, MCS, reference signal, MA signature, etc., that the UE will use to
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77/156 the following transmissions or retransmissions.
g. Feature hop pattern or RV hop pattern, or MA signature hop pattern for the following transmissions / retransmissions.
H. An explicit or implicit signal to indicate whether it is ACK or NACK and, optionally, a signal to indicate whether activity detection successfully detects the MA signature.
[00152] The additional information above can also be used for individual ACK / NACK via individual DCI, individual control channel or individual downlink shared channel (PDSCH).
[00153] Figure 14 illustrates a method performed by base station 100 and UE 102a, according to one embodiment. In step 452, base station 100 assigns UE 102a to a group, which has a corresponding GF_group_RNTI that distinguishes the group from the other groups. In step 453, the base station 100 determines the UE position index 102a in the group. In step 454, base station 100 transmits the GF_group_RNTI to UE 102a and the position index assigned to UE 102a, which is received by UE 102a in step 455. In step 456, UE 102a transmits a uplink message without concession using an MA signature, which is received by base station 100 in step 457. In step 458, the base station performs activity detection and attempts to decode the data. In step 459, base station 100 sends an ACK or NACK to UE 102a on a group ACK / NACK. The group ACK / NACK is sent to the DCI. In step 460, UE 102a searches for the group ACK / NACK in the search space defined by GF_group_RNTI. In step 461, UE 102a obtains the group ACK / NACK and reads its ACK or NACK in the UE position index 102a.
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78/156 [00154] Figure 15 is a method performed by base station 100 and UE 102a and 102b, according to an embodiment. In step 462, UE 102a transmits an uplink transmission without concession to base station 100, which is received by base station 100 in step 464. In step 466, UE 102b also transmits an uplink transmission without concession to the base station 100, which is received at step 468. Steps 462 and 464 can take place in parallel to steps 466 and 468. In step 470, base station 100 transmits a group ACK / NACK to UEs 102a and 102b, which may have any of the formats discussed above. The group ACK / NACK is received by UE 102a and 102b in step 472. In some embodiments, the group ACK / NACK can recognize all UE packets received within a given time window covering a block of time slots, TTIs or subframes. Such a group ACK / NACK will be referred to as an asynchronous group ACK / NAKC. The asynchronous group ACK / NACK can be in a predefined location, or defined in a system information block (SIB) or configured using RRC.
[00155] As an asynchronous group ACK / NACK can be recognizing multiple packets sent by the same UE (for example, in different TTIs), each ACK in the group ACK / NACK is identified using either the UE ID (or MA signature if uniquely identifies the UE) and other information that identifies the specific package being recognized. The other information may include, but is not limited to: the package ID; or the package arrival time; or an indication of the location of the package, such as the subframe or resource block where the package was sent; or an included HARQ process ID
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79/156 in the package. The asynchronous group ACK / NACK can be present in a control channel, data channel or dedicated acknowledgment channel.
[00156] The asynchronous group ACK / NACK can have a format similar to the one described for the group ACK / NACK in Figures 10 to 13. In the bitmap format of Figures 10 to 12, the addition of packet ID, time packet arrival number, subframe number, resource index without concession or HARQ ID can be added to the UE position index. In the format of the UE ID aggregated in Figure 13, the packet ID, packet arrival time, subframe number or non-concession resource index can be added as a field alone or as a field at the top of each UE ID or as a group index. For example, the asynchronous group ACK / NACK can contain a number of groups, each group containing the group ACK / NACK for each time interval.
[00157] In some modalities, an asynchronous group ACK / NACK can recognize all UE packets that have arrived since the previous asynchronous group ACK / NACK was sent.
[00158] In some modalities, the payload of the group ACK / NACK (asynchronous or not) is coded using an early error correction code (FEC) or a CRC.
[00159] As mentioned above, a group ACK / NACK includes UE identification information (for example, UE ID or MA signature) or package identification information (for example package ID or package arrival time), for each uplink transmission being recognized. In some embodiments, the UE identifies information or the package identity information can be
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80/156 transmitted separately or aggregated and protected together. For example, as mentioned above, the group ACK / NACK can be a single payload protected by a CRC. UEs know where to look for group ACK / NACK. For example, there may be a dedicated channel for the group ACK / NACK, which is known to the UEs. The group ACK / NACK location can be preconfigured, semi-persistently configured, or dynamically changed using a control channel.
[00160] Figure 16 illustrates an example of an asynchronous group ACK / NACK. A time-frequency partition is separated into five time intervals. In the first time slot, UE 1 sends a first packet and UE 2 also sends a first packet, both through a respective uplink transmission without concession. In a third interval, UE 1 transmits a second packet, UE 3 transmits a first packet and UE 4 transmits a first packet, each through a respective uplink transmission without concession. In a fourth time slot, the UE 5 transmits a first packet in an uplink transmission without concession. Then, after the end of the fifth time slot, the base station sends an asynchronous group ACK / NACK to the packets sent during the five time slots.
[00161] In some modalities, the group ACK / NACK can also carry NACKs. In situations where the group ACK / NACK is only loading NACKs (for example, no UE has had its data successfully decoded), then the group ACK can be called a group NACK.
[00162] In some modalities, the group ACK / NACK can
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81/156 be linked to the non-concession resources used. That is, if a UE group uses a particular time / frequency region or location A, then that UE group knows where to look for the group ACK / NACK, for example, the group ACK / NACK is in the time- frequency B on a downlink recognition channel.
[00163] In some modalities, the group ACK / NACK may have a fixed association with the UE uplink transmission time. For example, all UEs that send an uplink transmission without concession in time A can have their ACK / NACK'd transmissions in the group ACK / NACK.
[00164] In some modalities, the asynchronous group ACK / NACK can also be transmitted through a DCI common to the group. In this case, there may be a predefined group ID (for example, GF_group_RNTI). The group ID can change in different predefined locations (for example, depending on the frame and subframe number or time slot number), but known to both UEs sending the uplink transmissions without concession and the base station. The DCI common to the group can be sent in a search space defined by the group ID, and the CRC can be masked using the group ID. In some modalities, the asynchronous group ACK / NACK can be transmitted on a data channel indicated by a PDCCH that is configured by GF_group_RNTI.
Example of ACK / NACK signaling method [00165] Figure 17 is a method performed by UE 102a and base station 100, according to an embodiment.
[00166] In step 502, UE 102a sends data to the base station in an uplink transmission without concession.
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82/156 [00167] In step 504, the base station receives the uplink transmission without concession.
[00168] In step 506, the base station processes the uplink transmission without concession to determine the identity of UE 102a. Step 506 may comprise obtaining the UE ID for the UE 102a from the decoded data. Step 506 may, instead, comprise obtaining the MA signature used by the uplink transmission without concession, after activity detection.
[00169] In step 508, base station 100 transmits an ACK or NACK to UE 102a using one of the following methods: transmit the ACK / NACK on a dedicated downlink recognition channel, or transmit the ACK / NACK in individual DCI for UE 102a, or transmit the ACK / NACK on a resource partition on a downlink data channel indicated via DCI, or transmit the ACK / NACK as part of a group ACK / NACK. The details of each method are described above.
[00170] In step 510, the UE receives the ACK / NACK using a method corresponding to the method used by the base station 100 to send the ACK / NACK. For example, if the ACK / NACK was sent by the base station on a dedicated downlink recognition channel, then the UE 102a obtains the ACK / NACK from the dedicated downlink recognition channel.
UE configuration for uplink transmissions without concession [00171] A UE can be configured over the network (through the base station) for uplink transmission without
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83/156 concession. The configuration may change semi-statically.
[00172] In one mode, the configuration is performed using RRC signaling and may include (but is not limited to) defining one, some or all of the following parameters:
(1) Whether the UE needs to monitor a downlink control channel. In concession-based uplink communications, a UE can regularly monitor a downlink control channel to the DCI being communicated to the UE, for example, to receive a staggered lease to the UE. However, when the UE is configured to perform uplink transmissions without concession, the UE may not need to monitor the downlink control channel as often, or the UE may not need to monitor the downlink control channel in general. How many times (if any) the UE that performs uplink transmissions without a concession needs to monitor the downlink control channel can be defined by the network. For example, the UE that performs uplink transmissions without concession can be configured to monitor the downlink control channel once every T subframes, where T is a parameter configured by the network.
(2) The maximum number of retransmissions that can be performed by the UE. For example, the UE can be configured to continue sending retransmissions until an ACK is received, but only up to a maximum of K retransmissions. And if K retransmissions have been sent and an ACK has not yet been received, then the UE no longer sends any retransmissions and considers that the data has not been received and correctly decoded by the base station.
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84/156 (3) The resources that can be accessed by the UE for uplink transmissions and retransmissions without concession, for example, the resource hop pattern used by the UE. In some modalities, multiple resource hop patterns or multiple time-frequency resources without concession in a time interval are assigned to the same UE. In this case, when the UE has multiple packets to transmit or needs multiple TBs to transmit data, the UE can choose to transmit the multiple TBs through different time-frequency resources. For example, if two non-concession time-frequency regions in a time slot are assigned to the same UE, the UE can use one non-concession region to transmit a packet associated with one TB and the other region to transmit to another TB. Each TB can correspond to a different HARQ process. Each TB can be a transmission or retransmission of its corresponding TB independently.
(4) The MA signature tuples that must be used, or that can be used, by the UE to send transmissions and retransmissions. For example, the UE can be assigned to a particular tuple-3 in table 302 of Figure 4, or a particular tuple-2 in table 308 of Figure 5. The assignment can also or instead include an MA signature hop pattern , for example, a pattern indicating which reference signal should be used for the initial transmission, the first retransmission, the second retransmission, etc.
(5) The MCS used by the UE for uplink transmissions without concession, and whether (or for how much) the MCS should be reduced after the initial transmission. For example,
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85/156 an MCS hop pattern can be assigned to the UE for uplink transmission without concession. An initial transmission may have a high MCS, a first retransmission may have a smaller MCS, a second retransmission may have an even smaller MCS, etc.
(6) Whether the UE needs to monitor ACKs or NACKs after the initial transmission and whether a dedicated acknowledgment channel needs to be monitored. The monitoring frequency of the recognition channel can also be configured. In addition, or instead, the UE can be informed which of the various options described above will be used to communicate the ACK / NACK, for example, dedicated downlink recognition channel, individual DCI, downlink data channel, as part of a group ACK, and any relevant details.
[00173] Alternatively, some or all of the above parameters can be indicated via DCI information instead of using the upper layer RRC signaling. The UE would then be configured to check the DCI. The DCI may include the resource configuration that allows the UE to perform uplink transmission without concession, for example, an allocation of which resources to use.
[00174] Another parameter not mentioned in (1) to (6) above, but which can be configured via DCI, is:
(7) The resource in the subframe used for the transmission of uplink without concession. As an example, DCI can indicate the first resource block location in a subframe to which the UE is allowed to send an uplink transmission without concession. In some modalities, knowledge of the first block location
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86/156 resources in the subframe may allow the UE to determine the resource hop pattern for future packet-related retransmissions, for example, if there is a known mapping between a resource used for a non-concession uplink transmission and a pattern of corresponding jump having this feature.
No Concession Repeats and No Concession to Concession Based Switching [00175] There may be situations where it is beneficial for a UE to switch between non-concession uplink transmissions and concession-based uplink transmissions.
[00176] The escalation of an uplink transmission to a UE in response to the receipt of an uplink transmission without a concession can be referred to as a switch from no concession to a concession based, that is to say an uplink transmission without concession is received from a UE, and in response a concession based uplink transmission is staggered to that UE by the base station. A switch from non-concession to concession-based can be accomplished by sending a staggering concession to the UE that sent the uplink transmission without concession.
[00177] In some embodiments, base station 100 may perform a switch from non-concession to concession-based based on certain conditions. Any condition, or any combination of conditions, can be used by base station 100 to determine whether to perform a non-concession to concession-based switch. Examples of conditions include:
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87/156 (A) The non-grant message includes a buffer status report indicating that the UE has data (or more data) to send. In response, base station 100 can perform a non-concession to concession-based switch.
or (B) The data in the message without concession is unsuccessfully decoded. In response, base station 100 can perform a non-concession to concession-based switch.
or (C) Latency requirement. If a UE is close to its latency limit, then base station 100 can perform a non-lease to lease-based switch. Otherwise, the base station 100 may not perform the switch, in which case the base station 100 can only send an ACK or NACK without a stagger grant, or the base station 100 may not send anything. Any subsequent transmissions (or retransmissions) by the UE can then be sent via uplink transmissions without concession. More generally, regardless of the latency requirement, if base station 100 determines that a switch from non-concession to concession-based to a UE should not be performed, then that UE can continue transmissions / retransmissions without concession.
or (D) Number of transmissions. For example, if a UE sent several (e.g., three) data retransmissions via uplink transmission without concession, and the decryption of data by the base station still fails, then the base station can perform a non-concession to base switch. in concession for submitting a concession of
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88/156 scheduling for the next retransmission. In some embodiments, the number of retransmissions can be determined by a reference signal identification (for example, the reference signal used in the retransmission) or by a separate indicator sent by the UE in the uplink transmission without concession.
or (E) The UE may send an indicator indicating whether the UE wishes to switch to concession based uplink transmission, based on the circumstances or requirements known to the UE (for example, UE latency requirement, traffic load, conditions channel, etc.). Base station 100 can perform a non-concession to concession-based switch if the UE indicates a desire to switch to concession-based uplink transmission.
or (F) The traffic load of UEs without concession, for example, the number of UEs without concession arriving in a current or recent subframe (s). If the number of uplink transmissions without a concession or the number of UEs authorized to send uplink transmissions without a concession exceeds a certain threshold, then in response a switch from no-concession to concession-based can be performed for one or more UEs.
or (G) If there is a potential future collision from a currently detected UE operating in transmission mode without concession, then a switch from no concession to concession based can be performed to try to avoid the potential future collision.
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89/156 or (H) Quality of Service (QoS) Requirements. Depending on the QoS requirements of a UE that sends an uplink transmission without a concession, a switch from non-concession to concession-based to that UE can be performed.
[00178] In some embodiments, the DCI or scheduling information for switching from non-concession to concession-based may also include some or all of the following information:
(i) An indicator indicating whether, after the granted uplink transmission, the UE should send additional uplink transmissions / retransmissions through non-concession uplink transmissions, or whether the UE should continue in the concession-based mode, ie , wait for future concessions before sending additional uplink transmissions / retransmissions. In one embodiment, the indicator can be a value that is true by default. A value of true indicates to the UE that any retransmissions sent after the granted uplink transmission must be sent through uplink transmissions without concession and must continue without waiting for an ACK / NACK, until an ACK is received (or up to a maximum number K of retransmissions being reached). A false value indicates to the UE that any retransmissions sent after the granted uplink transmission must be sent through concession-based uplink transmissions.
or (ii) An indicator indicating whether the concession is for a
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90/156 single uplink transmission granted, or if the UE is granted to perform multiple transmissions, for example, multiple retransmissions. If the UE has a concession to perform multiple transmissions, then the indicator may indicate one, some or all of the following: (a) the maximum number of K retransmissions (for example, item (2) above); or (b) the allocation of a resource block for the first transmission (for example, item (7) above) or the resource jump pattern; or (c) the MA signature for the first transmission or the MA signature hop pattern (for example, item (4) above); or (d) the MCS for the initial transmission or an MCS hop pattern (for example, item (5) above).
[00179] Items (i) or (ii) may also be included in the DCI or scheduling information for an uplink communication granted that is not a non-concession to concession-based switch. For example, a UE may be operating in a concession-based mode, but the indicators in (i) and (ii) above may also be included in the scheduling or DCI information for some or all uplink communications granted to configure a UE for follow-up behavior.
[00180] In some embodiments, the UE 102a can be configured to send an initial transmission of a transport block (TB) (for example, a packet) and then automatically carry out retransmissions from the TB through uplink transmissions without subsequent concession. Retransmissions without automatic concession can be referred to as performing continuous TB repetitions. That is, an initial uplink transmission from the
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TB can be performed, followed by the continuous repetition of TB using uplink transmissions without subsequent concession. The initial transmission can be without concession or granted.
[00181] In some modalities, the TB repetitions may use different versions of redundancy, for example, RV 1 for the first repetition, RV 2 for the second repetition, etc. However, redundancy versions do not have to be different. In some modalities, TB repetitions may use different MCS, for example, the initial transmission may have a high MCS, the first repetition may have a smaller MCS, the second repetition may have an even smaller MCS, etc. However, the MCS of different repetitions need not be different.
[00182] In some modalities, the repetition can be performed on pre-configured resources or pre-configured jump patterns. For example, based on non-concession resources used by UE 102a to send the initial transmission, there may be predetermined fixed future resources in advance to send any repetitions related to the initial transmission. For example, if the transmission without initial concession uses time-frequency location A in a first TTI, then the first repetition must be sent in time-frequency location B in the next TTI, and the second repetition must be sent in the location of time-frequency C in the following TTI, etc.
[00183] Continuous repetitions may be performed by UE 102a until at least one of the following conditions is met:
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92/156 (1) A message is received from base station 100, indicating that base station 100 has successfully received and decoded the TB. The message can be an ACK, or at least it will be called an ACK here, as the message confirms that the TB has been successfully decoded. The ACK can have any of the formats described above (for example, sent on a dedicated downlink recognition channel, sent as an individual DCI, sent on a data channel, sent as part of a group ACK / NACK having any the formats of Figures 10 - 13, etc.). In some embodiments, the ACK may include a concession for UE 102a to send one or more additional TBs. If a grant is included as part of the ACK, the ACK does not need to be explicitly included. That is, if UE 102a sends a first TB in an uplink transmission without a concession, and in response receives a grant to UE 102a to send one or more additional TBs, then UE 102a assumes that the first TB has been decoded with success by base station 100. ACK is implied due to the fact that UE 102a has been granted the concession to send more TBs. In some embodiments, the recognition / indication of successful TB reception is in an UL grant from the base station. As previously described, the ACK return can contain an HARQ process number (or HARQ process ID or any attribute that identifies the HARQ process number or TB index, for example, MA signature index or index of access region without concession or combination of the two) that is used to identify the TB that the ACK targets if there are multiple TBs transmitted. The HARQ process ID can be implicitly or explicitly
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93/156 signaled to the base station on the uplink transmission without concession. An example of implicit signaling is whether the HARQ process ID is identifiable for the base station based on the MA signature used by the UE. The MA signature can be a reference signal or a coding / signature / sequence table used for a multiple access scheme (MA) or any other attributes described above. For example, if an MA scheme uses two different coding tables to transmit two TBs (corresponding to two HARQ processes). The base station identifies the coding table by detecting activity. The base station can then indicate the codebook table index or the corresponding HARQ process index in the lease, which identifies the TB for which the ACK is intended. In some embodiments, the HARQ process ID can be identified implicitly through different regions of access without concession. For example, if a UE is configured to be able to access two access regions without concession in a period of time. The UE can transmit two TBs that correspond to two different HARQ processes. In the UL grant, the grant access region index or the HARQ process ID can be indicated implicitly or explicitly, such that the UE can identify which TB the ACK is intended for. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID. The HARQ ID can be more robustly protected, so that the base station can identify it, even if it cannot successfully decode the data.
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94/156 or (2) The number of repetitions for TB reaches K. That is, if UE 102a has performed K retransmissions and an ACK has not yet been received from base station 100, then UE 102a gives up trying to send the TB for base station 100. In some embodiments, K is configured semi-statically by base station 100, such that base station 100 / network can adjust K over time.
or (3) A lease is received from the base station that performs a non-lease to lease-based switch, i.e., the base station 100 sends a lease to UE 102a to perform one or more of the retransmissions. If an uplink lease is successfully received for a slot / mini-slot for TB, the uplink lease allocation overrides the non-lease allocation for that slot / mini-slot for that TB, and the transmission / retransmission of the UE follows the uplink concession for that interval / mini-interval for that TB. As previously described, the grant may contain an HARQ process number (or HARQ process ID, or any attribute that identifies the HARQ process number or TB index, for example, MA subscription index or region index access without concession or combination of the two) which is used to identify which TB the concession is intended for if there are multiple IBs transmitted. The HARQ process ID can be implicitly or explicitly signaled to the base station in the uplink transmission without concession. An example of implicit signaling is whether the HARQ process ID is identifiable for
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95/156 the base station based on the MA signature used by the UE. The MA signature can be an RS or a coding / signature / sequence table used for a multiple access scheme (MA) or any other attribute described above. For example, if an MA scheme uses two different coding tables to transmit two TBs (corresponding to two HARQ processes). The base station identifies the coding table by detecting activity. The base station can then indicate the codebook table index or the corresponding HARQ process index in the concession, which identifies the TB for which the concession is intended. In some embodiments, the HARQ process ID can be identified implicitly through different regions of access without concession. For example, if a UE is configured to be able to access two access regions without concession in a period of time. The UE can transmit two TBs that correspond to two different HARQ processes. In the UL grant, the grant access region index or the HARQ process ID can be indicated implicitly or explicitly, in such a way that the UE can identify which TB the grant is intended for. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID. The HARQ ID can be more robustly protected, so that the base station can identify it, even if it cannot successfully decode the data. Note that this does not assume that the uplink concession is staggered based on the interval where the allocation without concession is based on a mini-interval (vice versa).
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96/156 [00184] As mentioned above, in some modalities there may be a switch from non-concession to concession-based to grant a retransmission after an initial transmission is sent through an uplink transmission without concession. For example, UE 102a can send an initial transmission and, in response, base station 100 can perform successful activity detection, but does not successfully decode the data in the initial transmission. Base station 100 therefore sends a lease to UE 102a to send one or more retransmissions.
[00185] In some embodiments, if the uplink grant for the retransmission is received in a time slot n, and the grant indicates a relay grant in the time slot n + k (where k> 0), then the UE 102a has two options:
(1) In the case where k> 1, UE 102a performs a repetition without continuous concession from the n + 1 interval, the n + k -1 interval, and then switches to the concession-based retransmission in the n + interval k. And if then k = 1 then UE 102a would perform concession-based retransmission in the next interval, n + 1.
or (2) In the case where k> 1, UE 102a stops performing repetitions without concession after interval n (that is, it does not perform repetition without concession in time interval n + 1 or any subsequent intervals), and UE 102a waits until n + k interval to perform concession-based retransmission according to the concession. And if k = 1, then UE 102a would perform concession-based retransmission in the next interval, n + 1.
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97/156 [00186] Figure 18 is a method performed by base station 100 and UE 102a, according to one modality. In step 552, UE 102a sends an initial transmission without granting a TB on a non-granting uplink resource, and using an MA subscription. In step 554, base station 100 receives the uplink transmission. At step 556, base station 100 successfully performs activity detection to identify the MA signature, but base station 100 is unable to successfully decode the data on the TB. In step 558, base station 100 therefore sends a lease to UE 102a. The concession schedules a retransmission of the TB in the subsequent time n + k. At step 560, the grant is received by UE 102a in time slot n. In step 562, UE 102a sends the granted retransmission, which is received by base station 100 in step 564. In one embodiment, between steps 560 and 562, UE 102a performs a retry without continuous concession for TB, for example, from interval n + 1 the interval n + k - 1. In another embodiment, after step 560, UE 102a does not send any repetitions without granting the TB, but instead waits and only sends the retransmission granted in step 562.
[00187] Figure 19 is a method performed by UE 102a, according to a modality.
[00188] In step 602, UE 102a receives from the base station 100 a message configuring parameters for one or more uplink communications without concession.
[00189] In step 604, UE 102a decodes the message to obtain the parameters. The parameters include: whether or how often the UE should monitor a downlink control channel; or a maximum number of retransmissions
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98/156 that can be performed by the UE; or resources that can be accessed by the UE for uplink transmissions and retransmissions without concession; or at least one MA signature that must be used by the UE; or the MCS used by the UE; or if the UE needs to monitor ACKs or NACKs after the initial transmission, or if a dedicated acknowledgment channel needs to be monitored; or a resource in a subframe used for uplink transmission without concession.
HARQ return [00190] Many different HARQ return scenarios are provided above for uplink transmissions without concession. The following applies to all of the above scenarios, whether there is continuous repetition or not, or whether the uplink transmission without concession is an initial transmission or a retransmission.
[00191] A TB is sent from UE 102a to base station 100 using an uplink transmission without concession. In response, the return of HARQ (e.g., an ACK / NACK, a lease, etc.) for uplink transmission without a lease is provided by base station 100 to UE 102a. In some embodiments, an acknowledgment / indication of successful TB reception (for example, an ACK) is in the form of an uplink lease from base station 100. As described earlier, in some embodiments the return of ACK / NACK can contain an HARQ process number (or HARQ process ID, or any attributes that identify the HARQ process number or TB index, for example, MA subscription index or non-grant access region index
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99/156 or a combination of the two), which is used to identify which TB the ACK / NACK is intended for if there are multiple TBs transmitted. The HARQ process ID can be implicitly or explicitly signaled to base station 100 on uplink transmission without concession from UE 102a. An example of implicit signaling is whether the HARQ process ID is identifiable for base station 100 based on the MA signature used by UE 102a in uplink transmission without concession. The MA signature can be a reference signal or a coding / signature / sequence table used for a multiple access (MA) scheme, or any other attributes described above. For example, if an MA scheme uses two different coding tables to transmit two TBs (corresponding to two HARQ processes). Base station 100 identifies the coding table by detecting activity. Then, the base station 100 can indicate the codebook table index or the corresponding HARQ process index in its lease, which identifies the TB for which the ACK is intended. In some embodiments, the HARQ process ID can be identified implicitly by the base station 100 through different regions of access without concession. For example, if a UE 102a is configured to be able to access two access regions without concession at a time interval. UE 102a can transmit two TBs that correspond to two different HARQ processes. In the uplink grant of base station 100, the grant access region index or HARQ process ID can be indicated implicitly or explicitly, such that UE 102a can identify for
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100/156 which TB the ACK is intended for. An example of explicit signaling is having a field in the uplink message without concession that indicates the HARQ process ID. The HARQ ID can be more robustly protected so that base station 100 can identify it, even if it cannot successfully decode the data.
[00192] For all return signaling HARQ (ACK / NACK or concession) , the repetitions continuous without concession of EU can optionally be interrupted
in advance for a concession or, optionally, interrupted in advance by an ACK before finishing the K repetitions. For example, if the UE received an ACK during K repetitions, the UE may stop additional repetitions if the number of repetitions does not reach K. In some other scenarios, the UE may perform continuous repetition until the repetition reaches K or a concession uplink is received. The ACK can be in any of the signaling formats described in this description (for example, it can be a DCI common to the group or an EU-specific DCI). If a staging grant is received during or after the K repetitions, which stagger a retransmission of the same TB, then the UE will switch to the TB grant-based relay on the resource configured in the staging concession.
[00193] In some modalities, if the UE finishes K repetitions of a TB, and the UE has not received a HARQ return (for example, an ACK / NACK or concession) yet, the UE can wait for a HARQ return (ACK / NACK or concession). If the UE does not receive an ACK or a lease from the base station within a predefined TI window after K repetitions
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101/156 to be transmitted, then the UE can take over NACK and perform retransmissions without granting TB. Non-grant retransmissions can be made on configured non-grant resources. Retransmissions without concession may include another set of K repetitions. In some other modalities, if the UE does not receive a NACK or concession from the base station within the predefined / configured T1 window after the K repetitions, the UE can take over the ACK and not perform any additional retransmissions until it is further scaled. In some other modalities, it is up to the UE to perform retransmissions without additional concession if no HARQ returns are received within the predefined time window after the K repetitions. There may be another predefined / configured time window T2 (starting from the transmission time without initial concession) or a maximum number of retransmissions without concession N the EU can carry out in such a way that if the time window is reached or the maximum number retransmissions without concession are carried out by the UE, so the UE must not carry out any retransmission / retry without concession without return from the base station. The parameters T1, T2 or N can be predefined or configured in EU-specific RRC signaling.
[00194] In some modalities, the UE can discharge the TB buffer immediately if an ACK is received for the TB during or after the K repetitions. The ACK can be in any of the forms of signaling described in the disclosure. In some other embodiments, the UE may simply retain additional repetition / retransmission of the same TB when an ACK is received. The UE can only flush the HARQ buffer from the
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TB of a transmission without a lease, if an uplink lease is received that schedules a new TB that is using the same HARQ process (or HARQ process ID) as the TB. In some embodiments, if the UE does not receive a NACK or grant from the base station within the predefined / configured TI window after finishing the transmission of the K repetitions, the UE can assume ACK and discharge the TB buffer, or the UE can assume ACK and do not flush the buffer and do not perform any additional retransmission until further scaling.
[00195] If retransmission without a concession is to be performed by the UE after not receiving any return within a window of K repetitions, the UE may perform a retransmission without concession on any of the resources without concession regardless of the corresponding HARQ process ID . In some other modalities, the UE can only be allowed to relay without concession on a non-concession resource that is mapped to the same HARQ process ID as the initial transmission without concession. The described procedure also works for the case where k = 1.
[00196] In an uplink transmission mode without concession, the UE can perform a transmission without concession after RRC signaling without DCI signaling / activation. The UE first performs an initial access process. The base station then selects the transmission resource without concession to the UE and configures the UE via indicating the transmission resource without concession through RRC signaling. The resource may include, but is not limited to, time, frequency resource, reference signal information, information
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103/156 of MCS / TBS, power control parameters, periodicity and resource displacement, RNTI without concession, repetition number K (K> = 1) etc. After the RRC signaling, the UE obtained the uplink transmission resources and can then perform the uplink transmission without any DCI signaling. After the first batch of data arrives at the UE, the UE can then perform the initial transmission without granting the first batch of data using the allocated non-granting transmission resources. In some embodiments, the UE operating in non-concession mode (a non-concession UE) may not monitor DCI before performing an initial transmission without concession, as it does not require DCI activation to be able to perform concession-free transmission. A UE performing the initial transmission without granting the data at time n can only start monitoring the DCI at time n + t_a, where t_a is the time at which the UE starts monitoring the DCI after the initial transmission. The unit of time can be an interval, a subframe, a mini-interval, or any measure of unit of time. t_a can be a predefined value or can be configured by the network and sent to the UE, for example, through UE-specific RRC signaling. If t_a is predefined, it can be defined as the first time that the UE expects to receive a return from DCI after the initial transmission without concession. In some modalities, t_a = 0 or 1, that is, the UE can check DCI immediately after transmission
initial without concession or check the DCI in next interval. THE DCI can to be an DCI common to group or specific to EU and can to be used for to transmit ACK / NACK or a concession in link ascending. In some
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104/156 modalities, the UE only monitors DCI or only monitors ACK / NACK after the K repetitions have ended. Suppose the K repetitions of the transmission without concession have ended at time m and the UE can only start monitoring DCI or monitoring ACK / NACK at time m + t_b, where t_b can also be predefined or configured in RRC signaling. The UE can optionally stop monitoring DCI in a time window after K repetitions end, for example, if the K repetitions end in time m, the UE can stop monitoring DCI in time m + t_c, where t_c can be predefined or configured on RRC signaling.
[00197] If an UE assumes an ACK after not receiving any HARQ or concession returns within a T1 window after K repetitions, the UE may stop additional repetition / retransmission until additional signaling. In some modalities, t_c is the same as Tl, that is, the UE stops monitoring DCI at time m + Tl, so that only one of them is predefined or configured in RRC signaling. In some other modalities, the UE assumes NACK after not receiving any HARQ or concession returns within a T1 window and begins to perform autonomous TB retransmission / repetition until an ACK or concession is received or until a maximum number of N or retransmissions maximum retransmission time T2 (starting from the initial transmission time without concession n) is received as previously described. The UE can stop monitoring DCI after η + T2 is reached or at time t_ c after the maximum number of retransmissions N is reached. After stopping the DCI monitoring for the transmission, the UE can monitor the DCI again after a time t_a of the next initial transmission without concession.
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105/156 [00198] In some embodiments, the UE can monitor DCI at all times before or after the initial transmission without concession, since there may be other functions (for example, transmission based on supported concession) that require DCI signaling. In some embodiments, the UE does not monitor DCI every TTi, but instead the UE can only monitor DCI every T_m TTi, where T_m can be predefined or configured in RRC signaling. This can also apply to the case where the UE only starts monitoring DCI at time t_a after the initial transmission without concession. In general, the time and whether to monitor DCI can be configured for each UE, for example, through RRC signaling.
Examples [00199] In view of, and in addition to the above, the following examples are disclosed.
[00200] Example 1: A method performed by a base station comprising: receiving an uplink transmission without concession from user equipment (UE) on uplink resources; perform activity detection to obtain the MA signature used by the UE in the uplink transmission without concession; attempt to decode data on the uplink transmission without concession; transmit, in a downlink recognition channel, a return comprising an ACK or a NACK; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and uplink resources.
[00201] Example 2: The method of example 1, in which the channel
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106/156 downlink recognition is a PHICH type channel.
[00202] Example 3: The method of example 1 or example 2, in which the orthogonal sequence used to transmit the return is based on the MA signature, and the time-frequency location of the return is based on the uplink resources.
[00203] Example 4: The method of any one of examples 1 to 3, in which the return delay in the downlink acknowledgment channel has a fixed relation with the resource access delay without concession used to send the uplink transmission without concession.
[00204] Example 5: The method of any of examples 1 to 4, further comprising the generation of the return for performing operations comprising: obtaining a bit representing the ACK or the NACK; repeating the bit to obtain a plurality of bits; modulate the plurality of bits to obtain symbols; and multiply the symbols by the orthogonal sequence.
[00205] Example 6: A base station comprising: a processor; and a computer-readable storage medium storing the programming for execution by the processor, the programming including instructions for performing steps according to a method in any of Examples 1 to 5.
[00206] Example 7: A base station comprising: at least one antenna for receiving an uplink transmission without concession from user equipment (UE) on uplink resources; a transmission module without concession to: (i) perform activity detection to obtain the MA signature used by the UE in
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107/156 uplink transmission without concession; (ii) attempting to decode data on the uplink transmission without concession; and (iii) causing a return transmission comprising an ACK or a NACK, on a downlink recognition channel; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink resources.
[00207] Example 8: A method performed by a user equipment (UE) comprising: transmitting a uplink transmission without concession to a base station on uplink resources, the uplink transmission without concession using an MA subscription; receiving feedback comprising an ACK or a NACK on a downlink recognition channel; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink resources.
[00208] Example 9: The method of example 8, in which the downlink recognition channel is a PHICH type channel.
[00209] Example 10: The method of example 8 or example 9, in which the orthogonal sequence used to transmit the return is based on the MA signature, and the time-frequency location of the return is based on the uplink resources.
[00210] Example 11: The method of any of the examples 8 to 10, in which return delay in the
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108/156 downlink acknowledgment has a fixed relationship with resource access timing without concession used to send the uplink transmission without concession.
[00211] Example 12: A user equipment (UE) comprising: a processor; and a computer-readable storage medium storing the programming for execution by the processor, the programming including instructions for performing steps according to a method in any of Examples 8 to 11.
[00212] Example 13: A user equipment (UE) comprising: at least one antenna for transmitting an uplink transmission without concession to a base station on uplink resources, the uplink transmission without concession using an MA subscription ; a decoder for decoding the return corresponding to the uplink transmission without concession and received in a downlink recognition channel, the return comprising an ACK or a NACK; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink resources.
[00213] Example 14: A method performed by a base station comprising: receiving a first uplink transmission without concession from a first user equipment (UE); receiving a second uplink transmission without concession from a second UE, transmitting a group ACK / NACK message having a payload that includes at least one ACK or NACK for the first uplink transmission without concession and a
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ACK or NACK for the second uplink transmission without concession.
[00214] Example 15: The method of example 14, in which the payload is a word comprising a bit indicating the ACK or NACK for the first link transmission
upward without concession and other bit indicating the ACK or O NACK for the second transmission in uplink without concession.[00215] Example 16: The method of example 14, on what The
payload is a word comprising a first pair of bits corresponding to the first uplink transmission without concession and a second pair of bits corresponding to the second uplink transmission without concession, in which each pair of bits includes a bit indicating whether activity detection was successful and another bit indicating whether data decoding was successful.
[00216] Example 17: The method of any of the examples 14 to 16, in which one index of position in the payload corresponds to the first UE, and another index of position in the payload corresponds to the second UE.
[00217] Example 18: The method of example 14, in which the payload comprises a plurality of UE IDs, and in which the presence of a UE ID in the payload indicates an ACK for a UE corresponding to that UE ID.
[00218] Example 19: The method of any of Examples 14 to 18, wherein the payload includes ACKs / NACKs for multiple HARQ process IDs.
[00219] Example 20: The method of any of examples 14 to 19, in which the payload is sent on a downlink control channel and is scrambled by a group ID.
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110/156 [00220] Example 21: The method of any of examples 14 to 19, in which the payload is sent on a downlink data channel.
[00221] Example 22: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions for performing steps according to a method in any of Examples 14 to 21.
[00222] Example 23: A base station comprising: at least one antenna for receiving a first uplink transmission without concession from a first user equipment (UE) and receiving a second uplink transmission without concession from a according to EU; a transmission module without concession to generate a group ACK / NACK message having a payload that includes at least one ACK or NACK for the first uplink transmission without concession and an ACK or NACK for the second link transmission ascending without concession.
[00223] Example 24: A method performed by a first user equipment (UE) comprising: sending a first uplink transmission without concession to a base station; receive a group ACK / NACK message having a payload that includes at least one ACK or NACK for the first uplink transmission without concession and an ACK or NACK for a second uplink transmission without concession from a according to EU.
[00224] Example 25: The method of example 24, in which the payload is a word comprising a bit indicating the
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ACK or NACK for the first link transmission
upward without concession and other bit indicating the ACK or O NACK for the second transmission in uplink without concession.[00225] Example 26: The method of example 24, on what The
payload is a word comprising a first pair of bits corresponding to the first uplink transmission without concession and a second pair of bits corresponding to the second uplink transmission without concession, in which each pair of bits includes a bit indicating whether activity detection was successful and another bit indicating whether data decoding was successful.
[00226] Example 27: The method of any of Examples 24 to 26, in which one index of the payload corresponds to the first UE, and another index of the payload corresponds to the second UE.
[00227] Example 28: The method of example 24, wherein the payload comprises a plurality of UE IDs, and in which the presence of a UE ID in the payload indicates an ACK for a UE corresponding to that UE ID.
[00228] Example 29: The method of any of Examples 24 to 28, wherein the payload includes ACKs / NACKs for multiple HARQ process IDs.
[00229] Example 30: The method of any of examples 24 to 29, in which the payload is received in a downlink control channel and is scrambled by a group ID.
[00230] Example 31: The method of any of Examples 24 to 29, in which the payload is received on a downlink data channel.
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112/156 [00231] Example 32: A user equipment (UE) comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions for performing steps according to a method in any of Examples 24 to 31.
[00232] Example 33: A first user equipment (UE) comprising: at least one antenna for transmitting a first uplink transmission without concession to a base station, a decoder for decoding a group ACK / NACK message having a charge useful that includes at least one ACK or NACK for the first uplink transmission without concession and an ACK or NACK for a second uplink transmission without concession from a second UE.
[00233] Example 34: A method carried out by a base station comprising: receiving a first uplink transmission without concession from a first user equipment (UE); receiving a second uplink transmission without concession from a second UE; transmit, to the first UE and the second UE, a group ACK / NACK message having a payload indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to the second transmission of uplink without concession.
[00234] Example 35: The method of example 34, in which before transmitting the group ACK / NACK message, the base station tries to decode first data in the first uplink transmission without concession and seconds
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113/156
data in second transmission in link upward without concession.[00235] Example 36: The method of example 34 or 35, in what the ACK / NACK group includes a concession granting an streaming uplink to first EU.
[00236] Example 37 The method of example 36, in which the concession grants a retransmission of data sent in the first uplink transmission without concession.
[00237] Example 38: The method of example 36, in which the concession implicitly indicates the NACK corresponding to the first uplink transmission without concession by staggering a retransmission of data sent in the first uplink transmission without concession.
[00238] Example 39: The method of example 36, in which the concession implicitly indicates the ACK corresponding to the first uplink transmission without concession for staggering a transmission of new data.
[00239] Example 40: The method of any of examples 34 to 39, in which the first UE and the second UE are in a group having a group identifier (ID), and in which the group ACK / NACK is associated to the group ID.
[00240] Example 41: The method of example 40, where the group ID is a temporary radio network identifier (RNTI).
[00241] Example 42: The method of example 40 or 41, in which the group ID is a function of the resources without concession in which the first uplink transmission without concession was sent.
[00242] Example 43: The method of example 42, in which the group ID is a function of a unit of time in which the
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114/156 first uplink transmission without concession was sent.
[00243] Example 44: The method of example 43, in which the unit of time is a time interval.
[00244] Example 45: The method of example 43, in which the group ID is also a function of the frame number in which the first uplink transmission without concession was sent.
[00245] Example 46: The method of example 42, in which the group ID is a function of a frequency location in which the first uplink transmission without concession was sent.
[00246] Example 47: The method of example 42, wherein the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession was sent.
[00247] Example 48: The method of example 42, in which the group ID is a function of at least one of a subframe, slot number, and frame number in which the first uplink transmission without concession was sent.
[00248] Example 49: The method of example 48, where the interval is a time interval.
[00249] Example 50: The method of any of examples 40 to 49, in which the group ID is configured in upper layer signaling.
[00250] Example 51: The method of example 50, further comprising signaling the group ID to the first UE and the second UE in radio resource control (RRC) signaling.
[00251] Example 52: The method of any of the examples
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115/156 to 50, in which the group ACK / NACK is transmitted in group downlink control information common to the group (DCI).
[00252] Example 53: The method of example 52, in which the DCI common to the group is sent on a downlink control channel in a search space defined by the group ID.
[00253] Example 54: The method of example 52 or 53, in which a cyclic redundancy check (CRC) of the DCI common to the group is masked by the group ID.
[00254] Example 55: The method of example 54, comprising the base station shuffling the DCI CRC common to the group using the group ID.
[00255] Example 56: The method of any of examples 34 to 55, wherein the payload is a word comprising a bit indicating the ACK or NACK corresponding to the first uplink transmission without concession and another bit indicating the ACK or the NACK corresponding to the second uplink transmission without concession.
[00256] Example 57: The method of any of examples 34 to 55, wherein the payload is a word comprising a first pair of bits corresponding to the first uplink transmission without concession and a second pair of bits corresponding to the second transmission uplink without concession, where each pair of bits includes a bit indicating whether activity detection was successful and another bit indicating whether data decoding was successful.
[00257] Example 58: The method of any of examples 34 to 55, in which one position in the payload corresponds to the first UE and another position in the payload corresponds to
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116/156 according to EU.
[00258] Example 59: The method of example 58, in which the position corresponding to the first UE is based on an MA signature.
[00259] Example 60: The method of example 59, in which the position corresponding to the first UE is known to the first UE based on the MA signature and resources without concession used by the first UE to send the first uplink transmission without concession.
[00260] Example 61: The method of example 58, in which the position corresponding to the first UE is signaled to the first UE before the first UE sends the first uplink transmission without concession.
[00261] Example 62: The method of example 61, in which the position corresponding to the first UE is signaled using an upper stratification signal.
[00262] Example 63: The method of example 62, in which the upper layer signaling is RRC signaling.
[00263] Example 64: The method of any of examples 34 to 63, in which the group ACK / NACK indicates an ACK for all received packets successfully decoded in a TTI or in a time interval or a subframe.
[00264] Example 65: The method of any of examples 34 to 63, wherein the payload comprises a plurality of UE IDs, and in which the presence of a UE ID in the payload indicates an ACK for a UE corresponding to that EU ID.
[00265] Example 66: The method of any of examples 34 to 63, wherein the payload includes ACKs / NACKs for multiple HARQ process IDs.
[00266] Example 67: The method of example 66, where an ID
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117/156 HARQ process associated with data in the first uplink transmission without concession is explicitly or implicitly indicated in the first uplink transmission without concession.
[00267] Example 68: The method of example 66, in which the data in the first uplink transmission without concession are associated with an HARQ process ID, and in which a position, in the payload, of the ACK or NACK corresponding to the first uplink transmission without concession is based on a position index corresponding to the first UE and the HARQ process ID.
[00268] Example 69: The method of example 66, in which the first UE is assigned to multiple positions in the payload, each of the positions associated with a respective MA signature or HARQ process ID.
[00269] Example 70: The method of any of examples 34 to 69, wherein the first uplink transmission without concession is one of a plurality of uplink repetitions of a transport block, and in which the ACK / NACK group is used to terminate the uplink repetitions.
[00270] Example 71: The method of example 70, in which the group ACK / NACK indicates an ACK corresponding to the first uplink transmission without concession in order to terminate the uplink repetitions.
[00271] Example 72: The method of any of examples 34 to 71, in which there is a fixed timing relationship between: (i) uplink time-frequency resources in which the first uplink transmission without concession and the second uplink transmission without
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118/156 concessions were sent, and (ii) downlink link frequency resources on which the group ACK / NACK is sent.
[00272] Example 73: The method of any of examples 34 to 71, in which there is a fixed timing relationship between: (i) a subframe or time unit during which the first uplink transmission without concession and the second uplink transmissions without concession were sent, and (ii) a subframe or time unit during which the group ACK / NACK is sent.
[00273] Example 74: The method of any of examples 34 to 71, in which the data in the first uplink transmission without concession is associated with an HARQ process ID, where an indication of the HARQ process ID is present in the downlink control information, and where the HARQ process ID indication is used by the first UE to identify that the data is being recognized.
[00274] Example 75: The method of example 34, in which the payload is sent on a downlink data channel.
[00275] Example 76: The method of example 75, further comprising transmitting downlink control information that indicates where to find the payload in the downlink data channel.
[00276] Example 77: The method of example 34, in which the payload includes a portion corresponding to the first uplink transmission without concession, in which the portion has a location in the payload mapped to an MA subscription used by the first transmission in
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119/156 uplink without concession, and in which the portion includes at least one of: a staggering concession for the first UE; advanced timing information (TA); a UE ID of the first UE; a temporary identity to be used for additional communication between the first UE and the base station; the ACK or NACK corresponding to the first uplink transmission without concession.
[00277] Example 78: The method of example 57, in which the first uplink transmission without concession carries first data, and in which the method further comprises: when the first pair of bits indicates that activity detection was not successful , then receive a retransmission of the first data from the first UE, the retransmission in the same redundancy (RV) version as the first uplink transmission without concession.
[00278] Example 79: The method of example 57, in which the first uplink transmission without concession carries first data, and in which the method further comprises: when the first pair of bits indicates that the activity detection was successful , but that data decoding was not successful, so receiving a retransmission of the first data from the first UE, the retransmission data in a different RV from the first uplink transmission without concession.
[00279] Example 80: A base station comprising: a receiver to receive a first uplink transmission without concession from a first user equipment (UE), and to receive a second uplink transmission without concession from a according to EU; a transmission module without concession to generate a
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120/156 group ACK / NACK message having a payload indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to the second uplink transmission without concession.
[00280] Example 81: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions that, when executed by the processor, cause the base station to execute the method of any of examples 34 to 79.
[00281] Example 82: A method performed by a user equipment (UE) comprising: transmitting a first uplink transmission without concession to a base station; receiving a group ACK / NACK message having a payload indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to a second uplink transmission without concession from one second HUH.
[00282] Example 83: The method of example 82, in which the first UE and the second UE are in a group having a group identifier (ID), and in which the group ACK / NACK is associated with the group ID.
[00283] Example 84: The method of example 83, where the group ID is a temporary radio network identifier (RNTI).
[00284] Example 85: The method of example 83 or 84, in which the group ID is a function of the resources without concession in which the first uplink transmission without
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121/156 grant is sent.
[00285] Example 86: The method of example 85, in which the group ID is a function of a unit of time in which the first uplink transmission without concession is sent.
[00286] Example 87: The method of example 86, where the unit of time is an interval of time.
[00287] Example 88: The method of example 86 or 87, in which the group ID is also a function of the frame number in which the first uplink transmission without concession is sent.
[00288] Example 89: The method of example 85, in which the group ID is a function of a frequency location in which the first uplink transmission without concession is sent.
[00289] Example 90: The method of example 85, wherein the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[00290] Example 91: The method of example 85, wherein the group ID is a function of at least one of a subframe, interval and frame number in which the first uplink transmission without concession is sent.
[00291] Example 92: The method of example 91, where the interval is a time interval.
[00292] Example 93: The method of any of examples 83 to 92, in which the group ID is configured in upper layer signaling.
[00293] Example 94: The method of example 93, further comprising receiving, from the base station, an indication of the ID
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122/156 group in radio resource control (RRC) signaling.
[00294] Example 95: The method of any of the examples 83 to 94, in which the group ACK / NACK is received in downlink control information common to the group (DCI).
[00295] Example 96: The method of example 95, in which the DCI common to the group is received on a downlink control channel in a search space defined by the group ID.
[00296] Example 97: The method of example 95 or 96, in which a cyclic redundancy check (CRC) of the DCI common to the group is masked by the group ID.
[00297] Example 98: The method of example 97, further comprising unscrambling the DCI CRC common to the group using the group ID.
[00298] Example 99: The method of any of Examples 82 to 98, wherein the payload is a word comprising a bit indicating the ACK or NACK corresponding to the first uplink transmission without concession and another bit indicating the ACK or the NACK corresponding to the second uplink transmission without concession.
[00299] Example 100: The method of any of examples 82 to 98, wherein the payload is a word comprising a first pair of bits corresponding to the first uplink transmission without concession and a second pair of bits corresponding to the second transmission uplink without concession, where each pair of bits includes a bit indicating whether activity detection was successful and another bit indicating whether data decoding was successful.
[00300] Example 101: The method of any of the examples
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123/156 to 98, where one position in the payload corresponds to the first UE and another position in the payload corresponds to the second UE.
[00301] Example 102: The method of example 101, in which the position corresponding to the first UE is based on an MA signature.
[00302] Example 103: The method of example 102, in which the position corresponding to the first UE is known to the first UE based on the MA signature and resources without concession used by the first UE to send the first uplink transmission without concession.
[00303] Example 104: The method of example 101, in which the position corresponding to the first UE is signaled to the first UE before the first UE sends the first uplink transmission without concession.
[00304] Example 105: The method of example 104, in which the position corresponding to the first UE is signaled using superior stratification signal.
[00305] Example 106: The method of example 105, wherein the upper layer signaling is RRC signaling.
[00306] Example 107: The method of any of Examples 82 to 106, in which the group ACK / NACK indicates an ACK for all received packets successfully decoded in a TTI or in a time frame or a subframe.
[00307] Example 108: The method of any of Examples 82 to 107, wherein the payload comprises a plurality of UE IDs, and in which the presence of a UE ID in the payload indicates an ACK for a UE corresponding to that EU ID.
[00308] Example 109: The method of example 82, where the payload includes ACKs / NACKs for multiple process IDs
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124/156 HARQ.
[00309] Example 110: The method of example 109, in which an HARQ process ID is associated with data in the first uplink transmission without concession, and in which the HARQ process ID is explicitly or implicitly indicated in the first transmission uplink without concession.
[00310] Example 111: The method of example 109, in which an HARQ process ID is associated with data in the first uplink transmission without concession, and in which a position, in the payload, of the ACK or the NACK corresponding to the first uplink transmission without concession is based on a position index corresponding to the first UE and the HARQ process ID.
[00311] Example 112: The method of example 109, in which the first UE is assigned with multiple payload positions, each of the positions associated with a respective MA signature or HARQ process ID.
[00312] Example 113: The method of any of Examples 82 to 112, wherein the first uplink transmission without concession is one of a plurality of uplink repetitions of a transport block, and in which the ACK / NACK group is used to terminate the uplink repetitions.
[00313] Example 114: The method of example 113, in which the group ACK / NACK indicates an ACK corresponding to the first uplink transmission without concession in order to terminate the uplink repetitions.
[00314] Example 115: The method of any of examples 82 to 114, in which there is a fixed timing relationship between: (i) uplink time-frequency resources
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125/156 in which the first uplink transmission without concession is sent, and (ii) downlink time-frequency resources in which the group ACK / NACK is received.
[00315] Example 116: The method of any of examples 82 to 114, in which there is a fixed timing relationship between: (i) a subframe or time unit during which the first uplink transmission without concession is sent and (ii) a subframe or unit of time during which the group ACK / NACK is received.
[00316] Example 117: The method of any of Examples 82 to 116, in which an HARQ process ID is associated with data in the first uplink transmission without concession, an indication of the HARQ process ID is present in the information downlink control, and the HARQ process ID indication is used by the first UE to identify that data is being recognized.
[00317] Example 118: The method of any of the examples 82 to 117, in which the payload is received in a downlink data channel.
[00318] Example 119: The method of example 118, further comprising receiving downlink control information that indicates where to find the payload in the downlink data channel.
[00319] Example 120: The method of any of Examples 82 to 119, wherein the payload includes a portion corresponding to the first uplink transmission without concession, wherein the portion has a location on the payload mapped to a subscription to MA used by the first uplink transmission without a concession, and in which the portion includes at least one of: a concession of
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126/156 staggering to the first EU; advanced timing information (TA); a UE ID of the first UE; a temporary identity to be used for additional communication between the first UE and the base station; the ACK or NACK corresponding to the first uplink transmission without concession.
[00320] Example 121: The method of example 95, further comprising decoding the DCI common to the group, including performing a CRC check using the group ID.
[00321] Example 122: The method of example 121, where the group ID is an RNTI.
[00322] Example 123: The method of example 95, further comprising searching for a search space on a downlink control channel using the group ID to obtain the DCI common to the group.
[00323] Example 124: The method of example 123, in which the search space that is searched for is a function of the uplink resources used to transmit the first uplink transmission without concession.
[00324] Example 125: The method of example 100, further comprising: when the first pair of bits indicates that activity detection was not successful, then retransmit data from the first uplink transmission without concession in the same version of redundancy (RV) than the first uplink transmission without concession.
[00325] Example 126: The method of example 100, further comprising: when the first pair of bits indicates that the activity detection was successful, but that the data decoding was not successful, then
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127/156 retransmit data from the first uplink transmission without concession to a different RV from the first uplink transmission without concession.
[00326] Example 127: The method of any of examples 82 to 126, wherein the group ACK / NACK includes a concession that grants an uplink transmission to the UE.
[00327] Example 128: The method of example 127, in which the concession grants a retransmission of data sent in the first uplink transmission without concession.
[00328] Example 129: A user equipment (UE) comprising: a transmitter for transmitting a first uplink transmission without concession to a base station; a receiver to receive a group ACK / NACK message having a payload indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to a second uplink transmission without concession from of a second EU.
[00329] Example 130: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions that, when executed by the processor, cause the UE to execute the method of any of examples 82 to 128.
[00330] Example 131: A method performed by a base station comprising: receiving an uplink transmission without concession from a user equipment (UE), the uplink transmission without concession carrying data corresponding to a first transport block ; transmit a concession to the UE, where
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128/156 the grant schedules a retransmission of the first transport block when decoding the first transport block fails or schedules a transmission of a second transport block when decoding the first transport block is successful.
[00331] Example 132: The method of example 131, in which the concession does not include an explicit ACK or an explicit NACK for the first transport block.
[00332] Example 133: The method of example 131 or 132, in which the lease is sent in the downlink control (DCI) information.
[00333] Example 134: The method of any of examples 131 to 133, in which the grant is sent as part of a group ACK / NACK.
[00334] Example 135: The method of any of examples 131 to 134, in which before transmitting the concession, the base station tries to decode the first transport block based on the data in the uplink transmission without concession.
[00335] Example 136: The method of any of examples 131 to 135, in which the grant implicitly indicates a NACK for the first transport block by staggering the retransmission of the first transport block.
[00336] Example 137: The method of any of examples 131 to 135, wherein the grant implicitly indicates an ACK for the first transport block by staggering the transmission of the second transport block.
[00337] Example 138: The method of any of examples 131 to 137, wherein the grant includes an HARQ process ID corresponding to the first transport block.
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129/156 [00338] Example 139: The method of any of examples 131 to 138, wherein the uplink transmission without concession is one of a plurality of uplink repetitions of the first transport block, and in which the concession terminates the uplink repetitions.
[00339] Example 140: A base station comprising: a receiver for receiving an uplink transmission without concession from a user equipment (UE), the uplink transmission without concession carrying data corresponding to a first transport block; a transmission module without a concession to generate a concession for the UE; wherein the concession schedules a retransmission of the first transport block when decoding the first transport block fails or schedules a transmission of a second transport block when decoding the first transport block is successful.
[00340] Example 141: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the base station to execute the method of any of examples 131 to 139.
[00341] Example 142: A method performed by a user equipment (UE) comprising: transmitting an uplink transmission without concession to a base station, the uplink transmission without concession carrying data corresponding to a first transport block; receive a lease from the base station, where the lease schedules a retransmission
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130/156 of the first transport block when decoding the first transport block failed at the base station or scheduling a transmission of a second transport block when decoding the first transport block was successful at the base station; transmit an uplink transmission according to the concession.
[00342] Example 143: The method of example 142, in which in response to the transmission of the uplink transmission without concession: an explicit ACK or an explicit NACK for the first transport block is not received by the UE.
[00343] Example 144: The method of example 142 or 143, in which the lease is received on the downlink control (DCI) information.
[00344] Example 145: The method of any of Examples 142 to 144, in which the grant is received as part of a group ACK / NACK.
[00345] Example 146: The method of any of Examples 142 to 145, wherein the grant implicitly indicates a NACK for the first transport block by staggering the retransmission of the first transport block.
[00346] Example 147: The method of any of Examples 142 to 145, wherein the grant implicitly indicates an ACK for the first transport block by staggering the transmission of the second transport block.
[00347] Example 148: The method of any of Examples 142 to 147, wherein the grant includes an HARQ process ID corresponding to the first transport block.
[00348] Example 149: The method of any of examples 142 to 148, wherein the uplink transmission without concession is one of a plurality of link repetitions
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131/156 ascending of the first transport block, and in which the concession ends the uplink repetitions.
[00349] Example 150: A user equipment (UE) comprising: a transmission module without concession to generate a message to be transmitted to a base station through an uplink transmission without concession, the message carrying data corresponding to a first transport block; a receiver to receive a lease from the base station, where the lease schedules a retransmission of the first transport block when decoding the first transport block failed at the base station or schedules a transmission of a second transport block when decoding the first block transport was successful at the base station; a transmitter to transmit an uplink transmission according to the concession.
[00350] Example 151: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions that, when executed by the processor, cause the UE to execute the method of any of examples 142 to 149.
[00351] Example 152: A method performed by a base station comprising: receiving an uplink transmission without concession from user equipment (UE) on uplink resources; transmit, in a downlink recognition channel, a return corresponding to the uplink transmission without concession, the return comprising an ACK or a NACK; where an orthogonal sequence used to transmit the
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132/156 return or a return time-frequency location is based on at least one of the MA subscription and the uplink capabilities.
[00352] Example 153: The method of example 152, in which the orthogonal sequence used to transmit the return is based on the MA signature, and the location of the return's frequency-frequency is based on the uplink resources.
[00353] Example 154: The method of example 152 or 153, in which the return delay in the downlink acknowledgment channel has a fixed relationship with the resource access delay without concession used to send the uplink transmission without concession.
[00354] Example 155: The method of any of examples 152 to 154, further comprising generating the return for performing operations comprising: obtaining a bit representing the ACK or NACK repeating the bit to obtain a plurality of bits; modulate the plurality of bits to obtain symbols; and multiply the symbols by the orthogonal sequence.
[00355] Example 156: The method of any of examples 152 to 155, wherein the downlink recognition channel is a PHICH type channel.
[00356] Example 157: A base station comprising: a receiver for receiving an uplink transmission without concession from user equipment (UE) on uplink resources; a transmission module without concession to generate, for transmission in a downlink recognition channel, a return corresponding to the transmission of uplink without concession, the return comprising an ACK or a NACK; on what
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133/156 an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink resources.
[00357] Example 158: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the base station to execute the method of any of examples 152 to 156.
[00358] Example 159: A method performed by a user equipment (UE) comprising: transmitting an uplink transmission without concession to a base station on uplink resources, the uplink transmission without concession using an MA subscription; receiving, in a downlink recognition channel, a return corresponding to the uplink transmission without concession, the return comprising an ACK or a NACK; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink capabilities.
[00359] Example 160: The method of example 159, in which the orthogonal sequence used to transmit the return is
based on signature in Mother the localization in time- frequency return is based on resources in link ascending. [00360] Example 161: 0 method from example 159 or 160 in
return delay on the downlink acknowledgment channel has a fixed relationship with
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134/156 resource access without concession used to send uplink transmission without concession.
[00361] Example 162: The method of any of examples 159 to 161, wherein the downlink recognition channel is a PHICH type channel.
[00362] Example 163: A user equipment (UE) comprising: a transmitter for transmitting a uplink transmission without concession to a base station on uplink resources, the uplink transmission without concession using an MA subscription; a decoder for decoding the return corresponding to the uplink transmission without concession and received in a downlink recognition channel, the return comprising an ACK or a NACK; wherein an orthogonal sequence used to transmit the return or a time-frequency location of the return is based on at least one of the MA signature and the uplink resources.
[00363] Example 164: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, the programming including instructions that, when executed by the processor, cause the UE to execute the method of any of examples 159 to 162.
[00364] Example 165: A method performed by a base station comprising: receiving, in uplink time-frequency resources, an uplink transmission without concession from a user equipment (UE); transmit, in downlink control information (DCI), return corresponding to the link transmission
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135/156 ascending without concession; where a DCI CRC is masked using an ID, and where the ID is a function of the uplink time-frequency resources in which the uplink transmission without concession was received.
[00365] Example 166: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the base station to execute the method of example 165.
[00366] Example 167: A method performed by UE comprising: transmitting, in uplink time-frequency resources, an uplink transmission without concession to a base station; receive, in downlink control information (DCI), the return corresponding to the uplink transmission without concession; where a DCI CRC is masked using an ID, and where the ID is a function of the uplink time-frequency resources where the uplink transmission without a concession was sent.
[00367] Example 168: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the UE to execute the method of example 167.
[00368] Example 169: A method performed by a base station comprising: transmitting, to a user equipment, an indication of a modulation and coding scheme (MCS) to be used by the UE for a
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136/156 uplink transmission without concession; receiving the uplink transmission without concession from the UE, the uplink transmission without concession carrying data having the MCS.
[00369] Example 170: The method of example 169, in which the indication is transmitted in radio resource control (RRC) signaling.
[00370] Example 171: The method of example 169 or 170, wherein the indication indicates an MCS hop pattern to be used by the UE for a plurality of uplink transmissions without concession.
[00371] Example 172: The method of example 171, in which the MCS hop pattern indicates that a first uplink transmission without a concession is to use a first MCS and a second uplink transmission without a concession is to use a second MCS, where the second MCS is less than the first MCS.
[00372] Example 173: The method of example 172, wherein the first uplink transmission without concession is a first repetition of a transport block and the second uplink transmission without concession is a second repetition of the transport block.
[00373] Example 174: A base station comprising: a transmitter to transmit, to a user equipment, an indication of a modulation and coding scheme (MCS) to be used by the UE for an uplink transmission without concession; a receiver to receive the uplink transmission without concession from the UE, the uplink transmission without concession carrying data having the MCS.
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137/156 [00374] Example 175: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the base station to execute the method of any of examples 169 to 173.
[00375] Example 176: A method performed by a user equipment (UE) comprising: receiving, from a base station, an indication of a modulation and coding scheme (MCS) to be used by the UE for a link transmission ascending without concession; transmitting the uplink transmission without concession to the base station, the uplink transmission without concession carrying data having the MCS.
[00376] Example 177: The method of example 176, in which the indication is received at the radio resource control (RRC) signaling.
[00377] Example 178: The method of example 176 or 177, in which the indication indicates an MCS hop pattern to be used by the UE for a plurality of uplink transmissions without concession.
[00378] Example 179: The method of example 178, in which the MCS hop pattern indicates that a first uplink transmission without a concession is to use a first MCS and a second uplink transmission without a concession is to use a second MCS, where the second MCS is less than the first MCS.
[00379] Example 180: The method of example 179, in which the first uplink transmission without concession is a first repetition of a transport block and the second
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138/156 uplink transmission without concession is a second repetition of the transport block.
[00380] Example 181: A user equipment (UE) comprising: a receiver to receive, from a base station, an indication of a modulation scheme and
coding (MCS) to be used fur EU for an streaming in uplink without concession; one transmitter for transmit link transmission
uplink without concession to the base station, uplink transmission without concession carrying data having the MCS.
[00381] Example 182: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the UE to execute the method of any of examples 176 through 180.
[00382] Example 183: A method performed by a base station, the method in which it comprises: receiving two uplink transmissions from a user equipment (UE) in the same time interval, the two uplink transmissions comprising a first uplink transmission received on the first uplink frequency resources and a second uplink transmission received on the second uplink frequency resources.
[00383] Example 184: The method of example 183, in which the first uplink transmission carries a first transport block corresponding to a first HARQ process, and the second link transmission
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Upward 139/156 carries a second transport block corresponding to a second HARQ process.
[00384] Example 185: The method of example 184, in which a HARQ process ID of the first HARQ process is implicitly identified by the first uplink time-frequency resources in which the first uplink transmission is received.
[00385] Example 186: A base station comprising: a receiver for receiving two uplink transmissions from a user equipment (UE) in the same time slot, the two uplink transmissions comprising a first uplink transmission received in the first uplink time-frequency resources and a second uplink transmission received in second uplink time-frequency resources.
[00386] Example 187: A base station comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the base station to execute the method of any of examples 183 to 185.
[00387] Example 188: A method performed by a user equipment (UE), the method in which it comprises: transmitting two uplink transmissions to a base station in the same time interval, the two uplink transmissions comprising a first uplink transmission sent on the first uplink time-frequency resources and a second uplink transmission sent in seconds
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140/156 uplink time-frequency resources.
[00388] Example 189: The method of example 188, in which the first uplink transmission carries a first transport block corresponding to a first HARQ process, and the second uplink transmission carries a second transport block corresponding to a second HARQ process.
[00389] Example 190: The method of example 189, in which a HARQ process ID of the first HARQ process is implicitly identified by the first uplink time-frequency resources on which the first uplink transmission is sent.
[00390] Example 191: A user equipment (UE) comprising: a transmitter for transmitting two uplink transmissions to a base station in the same time interval, the two uplink transmissions comprising a first uplink transmission sent on first uplink frequency resources and a second uplink transmission sent in second uplink frequency resources.
[00391] Example 192: A UE comprising: a processor; and a computer-readable storage medium storing programming for execution by the processor, programming including instructions that, when executed by the processor, cause the UE to execute the method of any of examples 188 to 190.
[00392] Example 193: A method performed by a base station comprising: receiving a first uplink transmission without concession from a first
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141/156 user equipment (UE); receiving a second uplink transmission without concession from a second UE; transmit a group ACK / NACK message to the first UE and the second UE, in which the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID, and where the group ID is a function of at least one of a subframe, slot number, and frame number on which the first uplink transmission without concession was sent.
[00393] Example 194: A method carried out by a first UE comprising: transmitting a first uplink transmission without concession to a base station; receive a group ACK / NACK message addressed to the first UE and a second UE, where the first UE and the second UE are in a group having a group identifier (ID), where the group ACK / NACK is associated with the group ID, and where the group ID is a function of at least one of a subframe, slot number, and frame number on which the first uplink transmission without concession was sent.
[00394] Example 195: A method performed by a base station comprising: receiving a first uplink transmission without concession from a first user equipment (UE); receiving a second uplink transmission without concession from a second UE; transmitting, to the first UE and the second UE, a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to the second uplink transmission without concession.
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142/156 [00395] Example 196: The method of example 195, in which the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID group, and where the group ID is a function of non-leased resources on which the first non-leased uplink transmission was sent.
[00396] Example 197: The method of example 195, in which the first UE and the second UE are in a group having a group ID, in which the group ACK / NACK is associated with the group ID, in which the ACK / Group NACK is transmitted in group downlink control information (DCI), and in which a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00397] Example 198: The method of example 197, in which the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession was sent.
[00398] Example 199: The method of example 197 or 198, where the group ID is a temporary radio network identifier (RNTI) and is signaled to the first UE in radio resource control (RRC) signaling.
[00399] Example 200: The method of any of examples 195 to 199, in which the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a first bit corresponding to the first uplink transmission without concession and a second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
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143/156 [00400] Example 201: The method of example 200, where a position of the first and second bits in the payload corresponds to at least one of an MA signature and an HARQ process ID of the first and second transmissions. uplink without concession.
[00401] Example 202: The method of example 200, in which a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first transmission of uplink without concession.
[00402] Example 203: A base station comprising: a receiver to receive a first uplink transmission without concession from a first user equipment (UE), and to receive a second uplink transmission without concession from a according to EU; a transmission module without concession to generate a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to the second uplink transmission without concession.
[00403] Example 204: The base station of example 203, where the first UE and the second UE are in a group having a group identifier (ID), where the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources on which the first uplink transmission without a lease was sent.
[00404] Example 205: The base station of example 203, where the first UE and the second UE are in a group having a group ID, where the group ACK / NACK is associated with the group ID, where the base station should transmit the ACK / NACK from
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144/156 group in group downlink control information (DCI) and to mask a cyclic redundancy check (CRC) of the group DCI by group ID.
[00405] Example 206: The base station of example 205, in which the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession was sent.
[00406] Example 207: The base station of any of examples 203 to 206, in which the group ACK / NACK message has a payload indicating the ACK or NACK, in which the payload comprises a first bit corresponding to first uplink transmission without concession and second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00407] Example 208: The base station of example 207, where a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions without concession.
[00408] Example 209: The base station of example 207 or 208, where the base station is to signal, for the first UE, a position of the first bit in the payload, using radio resource control (RRC) signaling, before the first UE sends the first uplink transmission without a concession.
[00409] Example 210: A method performed by a first user equipment (UE) comprising: transmitting a first uplink transmission without concession to
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145/156 a base station; receiving a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to a second uplink transmission without concession from a second UE.
[00410] Example 211: The method of example 210, in which the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources to which the first non-leased uplink transmission is sent.
[00411] Example 212: The method of example 210, in which the first UE and the second UE are in a group having a group ID, in which the group ACK / NACK is associated with the group ID, in which the ACK / Group NACK is received in group downlink control information (DCI), and in which a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00412] Example 213: The method of example 211 or 212, wherein the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[00413] Example 214: The method of any of Examples 211 to 213, where the group ID is a temporary radio network identifier (RNTI) and is signaled to the first UE in the radio resource control signaling ( RRC).
[00414] Example 215: The method of any of examples 211 to 214, in which the group ACK / NACK message has a payload indicating the ACK or NACK, in which the payload comprises a first bit corresponding to the first
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146/156 uplink transmission without concession and a second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00415] Example 216: The method of example 215, wherein a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions without concession.
[00416] Example 217: The method of example 215, in which a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first transmission of uplink without concession.
[00417] Example 218: A first user equipment (UE) comprising: a transmitter for transmitting a first uplink transmission without concession to a base station; a receiver to receive a group ACK / NACK message indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to a second uplink transmission without concession from a second UE .
[00418] Example 219: The first UE of example 218, where the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources on which the first uplink transmission without a lease is sent.
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147/156 [00419] Example 220: The first UE of example 218, where the first UE and the second UE are in a group having a group ID, where the group ACK / NACK is associated with the group ID, where the receiver must receive the group ACK / NACK in group downlink control information (DCI), and where a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00420] Example 221: The first UE of example 219 or 220, in which the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[00421] Example 222: The first UE of any of examples 218 to 221, in which the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a first bit corresponding to first uplink transmission without concession and second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00422] Example 223: The first UE of example 222, where a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions without concession.
[00423] Example 224: The first UE of example 222, in which a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first uplink transmission without concession.
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148/156 [00424] Example IA: A method performed by a base station comprising: receiving a first uplink transmission without concession from a first user equipment (UE); receiving a second uplink transmission without concession from a second UE; transmitting, to the first UE and the second UE, a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to the second uplink transmission without concession.
[00425] Example 2A: The method of Example IA, in which the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources on which the first uplink transmission without a lease was sent.
[00426] Example 3A: The method of Example IA, in which the first UE and the second UE are in a group having a group ID, in which the group ACK / NACK is associated with the group ID, in which the ACK / Group NACK is transmitted in group downlink control information (DCI), and in which a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00427] Example 4A: The method of Example 2A or Example 3A, wherein the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession was sent.
[00428] Example 5A: The method of Example 2A or Example 3A, where the group ID is a temporary radio network identifier (RNTI) and is signaled to the first UE in the
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149/156 radio resource control (RRC) signaling.
[00429] Example 6A: The method of either from Example IA to Example 5A, wherein the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a first bit corresponding to first uplink transmission without concession and second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00430] Example 7A: The method of Example 6A, wherein a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions without concession.
[00431] Example 8A: The method of Example 6A, in which a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first transmission of uplink without concession.
[00432] Example 9A: A base station comprising: a receiver to receive a first uplink transmission without concession from a first user equipment (UE), and to receive a second uplink transmission without concession from a according to EU; a transmission module without concession to generate a group ACK / NACK message indicating an ACK or a NACK corresponding to the first uplink transmission without concession and an ACK or a NACK corresponding to the second uplink transmission without concession.
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150/156 [00433] Example 10A: The base station of Example 9A, where the first UE and the second UE are in a group having a group identifier (ID), where the group ACK / NACK is associated with the ID group, and where the group ID is a function of non-leased resources on which the first uplink transmission without a lease was sent.
[00434] Example 11A: The base station of Example 9A, where the first UE and the second UE are in a group having a group ID, where the group ACK / NACK is associated with the group ID, where the base station must transmit the group ACK / NACK in group downlink control information (DCI) and to mask a cyclic redundancy check (CRC) of the group DCI by the group ID.
[00435] Example 12A: The base station of Example 10A or Example 11A, where the group ID is a function of at least one unit of time and frequency location on which the first uplink transmission without a concession was sent.
[00436] Example 13A: The base station of any of Example 9A to Example 12A, where the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a corresponding first bit the first uplink transmission without concession and a second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00437] Example 14A: The base station of Example 13A, where a position of the first and second bits in the payload corresponds to at least one of an MA signature and an ID
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151/156 of HARQ process of the first and second uplink transmissions without concession.
[00438] Example 15A: The base station of Example 13A, where the base station is for signaling, for the first UE, a position of the first bit in the payload, using radio resource control (RRC) signaling, before the first UE to send the first uplink transmission without concession.
[00439] Example 16A: A method performed by a first user equipment (UE) comprising: transmitting a first uplink transmission without concession to a base station; receiving a group ACK / NACK message indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to a second uplink transmission without concession from a second UE.
[00440] Example 17A: The method of Example 16A, in which the first UE and the second UE are in a group having a group identifier (ID), in which the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources on which the first non-leased uplink transmission is sent.
[00441] Example 18A: The method of Example 16A, in which the first UE and the second UE are in a group having a group ID, where the group ACK / NACK is associated with the group ID, where the ACK / Group NACK is received in group downlink control information (DCI), and in which a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00442] Example 19A: The method of Example 17A or Example
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152/156
18A, wherein the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[00443] Example 20A: The method of Example 17A or Example 18A, where the group ID is a temporary radio network identifier (RNTI) and is signaled to the first UE in radio resource control (RRC) signaling .
[00444] Example 21A: The method of any of Example 16A to Example 2 0A, wherein the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a corresponding first bit the first uplink transmission without concession and the second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00445] Example 22A: The method of Example 21A, wherein a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions without concession.
[00446] Example 23A: The method of Example 21A, in which a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first transmission of uplink without concession.
[00447] Example 24A: A first user equipment (UE) comprising: a transmitter for transmitting a first uplink transmission without concession for
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153/156 a base station; a receiver to receive a group ACK / NACK message indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to a second uplink transmission without concession from a second UE .
[00448] Example 25A: The first UE of Example 24A, where the first UE and the second UE are in a group having a group identifier (ID), where the group ACK / NACK is associated with the group ID, and where the group ID is a function of non-leased resources on which the first uplink transmission without a lease is sent.
[00449] Example 26A: The first UE of Example 24A, where the first UE and the second UE are in a group having a group ID, where the group ACK / NACK is associated with the group ID, where the receiver must receive the group ACK / NACK in group downlink control information (DCI), and in which a cyclic redundancy check (CRC) of the group DCI is masked by the group ID.
[00450] Example 27A: The first UE of Example 25A or Example 26A, where the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[00451] Example 28A: The first UE of any of Example 24A to Example 27A, where the group ACK / NACK message has a payload indicating the ACK or NACK, where the payload comprises a corresponding first bit to the first uplink transmission without concession and a second bit corresponding to the second link transmission
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154/156 ascending without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[00452] Example 29A: The first UE of Example 28A, where a position of the first and second bits in the payload corresponds to at least one of an MA signature and a HARQ process ID of the first and second uplink transmissions. without concession.
[00453] Example 30A: The first UE of Example 28A, where a position of the first bit in the payload is signaled to the first UE, using radio resource control (RRC) signaling, before the first UE sends the first transmission uplink without concession.
Conclusion [00454] Although the present invention has been described with reference to specific features and modalities thereof, various modifications and combinations can be made without departing from the invention. The description and drawings are, therefore, considered simply as an illustration of some embodiments of the invention, as defined by the appended claims, and are contemplated to cover any and all modifications, variations, combinations or equivalents that fall within the scope of the present invention. . Therefore, although the present invention and its advantages have been described in detail, various changes, substitutions and changes can be made here without departing from the invention as defined by the appended claims. In addition, the scope of the present application is not intended to be limited to the particular modalities of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification.
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As an ordinary person skilled in the art will readily appreciate from the disclosure of the present invention, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or to be further developed, that perform substantially the same function or substantially achieve the same result as the corresponding modalities described herein can be used in accordance with the present invention. Accordingly, the appended claims are intended to include within its scope such processes, machines, manufacture, compositions of matter, means, methods or steps.
[00455] In addition, any module, component or device exemplified herein that executes instructions may include or have access to a non-transitory computer / processor readable storage medium or media for storing information, such as computer / processor readable instructions, data structures, program modules or other data. A non-exhaustive list of examples of non-transient computer-readable storage medium / processor includes magnetic tapes, magnetic tape, magnetic disk storage or other magnetic storage devices, optical discs such as compact disc read-only memory (CD-ROM) , digital video discs or digital versatile discs (DVDs), Blu-ray ™ Disc or other optical, volatile and non-volatile, removable and non-removable storage media implemented in any method or technology, random access memory (RAM), memory read-only (ROM), electrically erasable programmable read-only memory (EEPROM), memory
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156/156 flash or other memory technology. Any non-transitory computer / processor storage medium can be part of a device or accessible or connectable to it. Any application or module described here can be implemented using computer-readable / executable instructions that can be stored or otherwise maintained by that non-transitory computer / processor readable storage medium.

权利要求:
Claims (15)
[1]
1. Method performed by a base station (100) characterized by the fact that it comprises:
receiving (464) a first uplink transmission without concession from a first user equipment, UE;
receiving (468) a second uplink transmission without concession from a second UE;
transmit (470), for the first UE and for the second UE, a negative acknowledgment / acknowledgment message, group ACK / NACK indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to the second uplink transmission without concession, where the first UE and the second UE are in a group having a group identifier, ID, where the group ACK / NACK is associated with the group ID, where the ACK / NACK group data is transmitted in the downlink control information common to the group, DCI, and in which a cyclic redundancy check, CRC, of the DCI common to the group is masked by the group ID.
[2]
2. Method according to claim 1, characterized by the fact that the group ID is a function of resources without concession in which the first uplink transmission without concession was sent.
[3]
3. Method, according to claim 1 or 2, characterized by the fact that the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession was sent.
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2/4
[4]
4. Method according to claim 1 or 2, characterized by the fact that the group ID is a temporary radio network identifier, RNTI, and is signaled to the first UE in radio resource control signaling, RRC .
[5]
5. Method according to any of the claims
1 to 4, characterized by the fact that the group ACK / NACK message has a payload that indicates the ACK or NACK, in which the payload comprises a first bit corresponding to the first uplink transmission without concession and a second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[6]
6. Method according to claim 5, characterized by the fact that a position of the first and second bits in the payload corresponds to at least one of a multiple access signature, MA and a HARQ process ID of the first and second uplink transmissions without concession.
[7]
7. Method, according to claim 5, characterized by the fact that a position of the first bit in the payload is signaled to the first UE, using signaling of
radio resource control, RRC, before of first HUH send the first transmission of link upward without concession. 8. Featured base station fur fact that is configured to run the method according defined in
any of claims 1 to 7.
[8]
9. Method performed by a first user equipment, UE, characterized by the fact that it comprises:
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3/4 transmit (462) a first uplink transmission without concession to a base station;
receive (472) a negative acknowledgment / acknowledgment message, group ACK / NACK indicating an ACK or NACK corresponding to the first uplink transmission without concession and an ACK or NACK corresponding to a second uplink transmission without concession from a second UE, in which the first UE and the second UE are in a group having a group identifier, ID, in which the group ACK / NACK is associated with the group ID, in which the group ACK / NACK is received in the downlink control information common to the group, DCI, and where a cyclic redundancy check, CRC, of the DCI common to the group is masked by the group ID.
[9]
10. Method, according to claim 9, characterized by the fact that the group ID is a function of resources without concession, in which the first uplink transmission without concession is sent.
[10]
11. Method according to claim 9 or 10, characterized by the fact that the group ID is a function of at least one unit of time and frequency location in which the first uplink transmission without concession is sent.
[11]
12. Method according to claim 9 or 10, characterized by the fact that the group ID is a temporary radio network identifier, RNTI, and is signaled to the first UE in radio resource control signaling, RRC .
[12]
13. Method according to any of the claims
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4/4
9 to 12, characterized by the fact that the group ACK / NACK message has a payload that indicates the ACK or NACK, in which the payload comprises a first bit corresponding to the first uplink transmission without concession and a second bit corresponding to the second uplink transmission without concession, where each bit indicates whether the activity detection was successful or if data decoding was successful.
[13]
14. Method according to claim 13, characterized in that a position of the first and second bits in the payload corresponds to at least one of a multiple access signature, MA and a HARQ process ID of the first and second uplink transmissions without concession.
[14]
15. Method according to claim 13, characterized by the fact that a position of the first bit in the payload is signaled to the first UE, using radio resource control signaling, RRC, before the first UE sends the first transmission uplink without concession.
[15]
16. First user equipment, UE, characterized by the fact that it is configured to perform the method as defined in any of claims 9 to 15.

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

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