TABLE 1

rrc-ConfiguredUplinkGrant	SEQUENCE {
timeDomainOffset	INTEGER (0..5119),
timeDomainAllocation	INTEGER (0..15),
frequencyDomainAllocation	BIT STRING (SIZE(18)),
antennaPort	INTEGER (0..31),
dmrs-SeqInitialization	INTEGER (0..1)
OPTIONAL, -- Cond NoTransformPrecoder
precodingAndNumberOfLayers	INTEGER (0..63),
srs-ResourceIndicator	INTEGER (0..15),
mcsAndTBS	INTEGER (0..31),
frequencyHoppingOffset	INTEGER (1.. maxNrofPhysicalResourceBlocks−1)
OPTIONAL, -- Need M

pathlossReferenceIndex	INTEGER	(0..maxNrofPUSCH-
PathlossReferenceRSs−1),
...
}

It may be desired to implement a NR Uu capable of controlling both NR sidelink and LTE sidelink. In LTE V2X, the Uu interface is used to configure the WTRU for sidelink communications, e.g., resource pool configurations, PSSCH transmission configurations, synchronization signal configurations, mode 4 WTRU spectrum sensing configurations, etc. The Uu interface also provides a dynamic resource allocation formode 3 WTRUs.

Since NR has different physical layer structures and procedures from LTE, the NR Uu interface may need to be modified from the LTE Uu interface. Further, unlike the LTE sidelink, which supports only broadcast, the NR sidelink may support group-cast or unicast. Thus, the NR Uu interface may need to support NR sidelink group-cast or unicast. Accordingly, it may be desired to modify the NR Uu interface to support the configuration and dynamic resource allocation for NR unicast or group-cast sidelink.

The NR Uu interface may be implemented so as to support both LTE sidelink and NR sidelink simultaneously. For example, if amode 3 vehicle is communicating with other vehicles via an LTE sidelink, and if this vehicle moves out of the coverage of LTE network, it cannot further obtain sidelink transmission resources from the LTE eNB. However, if this vehicle is in coverage of NR gNB, it may still obtain the resource allocation from the NR gNB for its LTE sidelink transmissions.

Accordingly, it may be desired to implement a NR Uu interface such that it supports the dynamic resource allocation for LTE sidelink. Further, the NR Uu interface may need to be enhanced to have the flexibility to dynamically adjust the number of repetitions in grant free sidelink transmissions, e.g., due to resource limitations or other factors.

In LTE V2X, only one modulation and coding scheme (MCS) table is used. In NR URLLC use cases, two MCS tables could be used. Both MCS tables may support up to 64QAM modulation, while one MCS table contains lower spectrum efficiency entries (e.g., down to 30/1024*2) than the other (e.g., legacy) MCS table. The selection of which MCS table to use may depend on RRC configurations or may be dynamically indicated by physical layer.

Since V2X is considered as an application use scenario of URLLC and it has the reliability requirement of 1-10⁻⁵in several use cases, it is reasonable that V2X uses both MCS tables. Hence, the configuration and dynamic indication of which MCS table is used for NR V2X sidelink transmissions, may need to be designed.

Some embodiments include a NR Uu enhancement to control NR and LTE sidelink.FIG. 3 is a Venn diagram illustrating an example usage scenario for a NR Uu enhancement to control LTE sidelink. InFIG. 3,vehicle 1 is a moIn LTE V2X, there are two modes for WTRU.

Mode 3: WTRU obtains the sidelink transmission resources from network (i.e., eNB)

Mode 4: WTRU autonomously selects/determines the sidelink transmission resources by itself, via some sensing and resource selection procedure.de 3 WTRU, and it communicates with other vehicles (e.g.,vehicle 2 and vehicle 3) via a LTE sidelink.

FIG. 3 illustrates anexemplary scenario300 of NR Uu enhancement to controlLTE sidelink310.Vehicle 1320 is amode 3 WTRU capable of communicating withvehicle 2330(a) andvehicle 3330(b). Initially,vehicle 1320 is within an LTE coverage area and obtains resources for its sidelink transmissions from theLTE eNB340. Later,vehicle 1320 may move out of LTE coverage and into NR coverage. TheNR gNB350 may communicate withvehicle 1320 via an NR Uu link360.Vehicle 1320 may maintain theLTE sidelink310 as well as the sidelink channel configuration fromNR gNB350 via an NR Uu link360.

Initially,vehicle 1 is within LTE coverage, and it obtains the resources for its sidelink transmissions from the LTE eNB. Later,vehicle 1 moves out of LTE coverage, but it is in the coverage of NR. The NR gNB communicates withVehicle 1 via an NR Uu link. To maintain the LTE sidelink,vehicle 1 wishes to receive the sidelink transmission resource information, as well as the sidelink channel configurations, from NR gNB via NR Uu link.

Some examples include a WTRU procedure for configuring NR V2X sidelink monitoring. In some examples, a WTRU is configured by a higher layer to receive V2X sidelink communications. Table 2 includes pseudocode for an example procedure may be followed for the WTRU in such cases, to determine the parameters for receiving V2X sidelink communications:

TABLE 2

If the WTRU is in coverage on the frequency used for V2X sidelink communication
If the frequency used to receive V2X sidelink communication is included in v2x-
InterFreqInfoList, configure lower layers to monitor sidelink control information in v2x-CommRxPool
of v2x-InterFreqInfoList.
Elseif the frequency used to receive V2X sidelink communication is included in v2x-
InterRATInfoList, configure lower layers to monitor sidelink control information in v2x-CommRxPool
of v2x-InterRATInfoList.
Else, configure lower layers to monitor sidelink control information in v2x-CommRxPool of SIB-
V2X or RRCConnectionReconfiguration.
Else (WTRU is out of coverage)
If the frequency used to receive V2X sidelink communication is included in v2x-
InterFreqInfoList, configure lower layers to monitor sidelink control information in v2x-CommRxPool
of v2x-InterFreqInfoList.
Elseif the frequency used to receive V2X sidelink communication is included in v2x-
InterRATFreqInfoList, configure lower layers to monitor sidelink control information in v2x-
CommRxPool of v2x-InterRATFreqInfoList.
Else, configure lower layers to monitor sidelink control information in v2x-CommRxPool of SL-
V2X-Preconfiguration.

Table 3 includes pseudocode for an alternative expression of this example procedure:

TABLE 3

If the frequency used to receive V2X sidelink communication is included in v2x-
InterFreqInfoList, configure lower layers to monitor sidelink control information in v2x-CommRxPool
of v2x-InterFreqInfoList.
Elseif the frequency used to receive V2X sidelink communication is included in v2x-
InterRATFreqInfoList, configure lower layers to monitor sidelink control information in v2x-
CommRxPool of v2x-InterRATFreqInfoList.
Elseif the UE is in coverage on the frequency used for V2X sidelink communication
configure lower layers to monitor sidelink control information in v2x-CommRxPool of SIB-V2X or
RRCConnectionReconfiguration.
Else, configure lower layers to monitor sidelink control information in v2x-CommRxPool of
SL-V2X-Preconfiguration.

FIG. 4 is a flowchart illustrating an example WTRU procedure for configuring NR V2X sidelink communication monitoring.WTRU procedure400 is used to configure NR V2X sidelink communication monitoring. If the frequency is used to receive V2X sidelink communication included in v2x-InterFreqInfoList410, lower layers may be configured to monitor SCI, based on v2x-InterFreqInfoList420. Otherwise, if the frequency used to receive V2X sidelink communication is included in v2x-InterRATInfoList430; lower layers may be configured to monitor SCI, based on v2x-InterRATInfoList440. Otherwise, if the WTRU is in coverage in a frequency forNR V2X sidelink450, lower layers may be configured to monitor SCI, based on v2CommRxPool in SIB orRRCConnectionReconfiguration460. Otherwise, if the WTRU is not in coverage, lower layers may be configured to monitor SCI, based on v2x-CommRxPoolList in SL-V2X-Preconfiguration470.

In the example procedures described above and with respect to Tables 2 and 3, andFIG. 4, the v2x-InterRATInfoList may be a list of several neighboring frequencies for LTE V2X sidelink communication. Thus, the data structure of v2x-InterRATInfoList may be the same as “SL-InterFreqInfoListV2X-r14”.

The data structure of v2x-InterFreqInfoList may be defined as “SL-InterFreqInfoListV2X-r16”, which could have different SL-CommResourcePoolV2X parameter definitions from that of LTE. For example, NR generally has a larger bandwidth than LTE, and it supports up to 275 Resource Blocks (RBs) in a channel. Accordingly, the values of “startRB-Subchannel,” “startRB-PSCCH-Pool,” and “SizeSubchannel” may be different from LTE. This is shown as follows. Furthermore, the number of sub-channels in a channel for NR could be larger to support more V2X sidelink communication.

TABLE 4

SL-InterFreqInfoListV2X-r16 ::= SEQUENCE (SIZE (0..maxFreqV2X-1-r16)) OF SL-InterFreqInfoV2X-r16

SL-InterFreqInfoV2X-r16 ::=

SEQUENCE {

	v2x-SchedulingPool	SL-CommResourcePoolV2X-r16
	...

}
SL-CommResourcePoolV2X-r16 ::=	SEQUENCE {

sizeSubchannel

ENUMERATED {

	n4, n5, n6, n8, n9, n10, n12, n15, n16, n18, n20, n25, n30,
	n48, n50, n72, n75, n96, n100, n120, n150, n160, n180, n200,
	n250, n275, spare6, spare5, spare4, spare3, spare2, spare1},

numSubchannel

ENUMERATED {n1, n3, n5, n8, n10, n15, n20, n25, n30, n40, n50,

		spare5, spare4, spare3, spare2, spare1},
	startRB-Subchannel	INTEGER (0..274),

	startRB-PSCCH-Pool	INTEGER (0..274)	OPTIONAL,	-- Need OR
	...

}

The v2x-InterFregInfoList and v2x-InterRATInfoList defined above with respect to Table 4 may be component elements of the IEs of SL-V2X-ConfigDedicated, SL-V2X-ConfigCommon and SL-V2X-PreconfigFregInfo.

TABLE 5

SL-V2X-ConfigDedicated ::=	SEQUENCE {
v2x-InterFreqInfoList	SL-InterFreqInfoListV2X-r16
v2x-InterRATInfoList	SL-InterFreqInfoListV2X-r14
......
}
SL-V2X-ConfigCommon ::=	SEQUENCE {
v2x-InterFreqInfoList	SL-InterFreqInfoListV2X-r16
v2x-InterRATInfoList	SL-InterFreqInfoListV2X-r14
......
}
SL-V2X-PreconfigFreqInfo ::=	SEQUENCE {
v2x-CommRxPoolList	SL-PreconfigV2X-RxPoolList-r16,
v2x-CommTxPoolList	SL-PreconfigV2X-TxPoolList-r16,
v2x-CommRxPoolList-InterRAT	SL-PreconfigV2X-RxPoolList-r14,
v2x-CommTxPoolList-InterRAT	SL-PreconfigV2X-TxPoolList-r14,
......
}

SL-PreconfigV2X-RxPoolList ::= SEQUENCE (SIZE (1..maxSL-V2X-RxPoolPreconf)) OF SL-

CommResourcePoolV2X-r16

SL-PreconfigV2X-TxPoolList ::= SEQUENCE (SIZE (1..maxSL-V2X-TxPoolPreconf)) OF SL-

CommResourcePoolV2X-r16

SL-V2X-PreconfigFreqList ::= SEQUENCE (SIZE (1..maxFreqV2X)) OF SL-V2X-

PreconfigFreqInfo

The three IEs defined above with respect to Table 5 may be contained in SIB-V2X, RRCConnectionReconfiguration and SL-V2X-Preconfiguration, respectively.

Some examples include a WTRU procedure for configuring NR V2X sidelink transmissions. In some examples, a WTRU is configured by higher layers to transmit V2X sidelink communication. In such examples, the following example procedure, expressed in pseudocode in Table 6 may be implemented for the WTRU to determine the parameters for transmitting V2X sidelink communication.

TABLE 6

If the UE is in coverage on the frequency used for V2X sidelink communication or
if the frequency used to transmit V2X sidelink communication is included in v2x-InterFreqInfoList or v2x-
InterRATInfoList,
If UE is in RRC_CONNECTED,
If UE is configured with commTxResources= scheduled,
If some exceptional condition occurs, then apply Random Selection using the pool
indicated in v2x-CommTxPoolExceptional.
Otherwise, configure lower layers to request gNB to assign transmission resources for
V2X sidelink communications.
Elseif UE is configured with v2x-CommTxPoolNormalDedicated or v2x-CommTxPoolNormal in
the entry of v2x-InterFreqInfoList, then apply Sensing based selection using the pool indicated in v2x-
CommTxPoolNormalDedicated or v2x-CommTxPoolNormal.
Elseif UE is configured with v2x-CommTxPoolNormalDedicated or v2x-CommTxPoolNormal in
the entry of v2x-InterRATInfoList, then apply Sensing based selection using the pool indicated in v2x-
CommTxPoolNormalDedicated or v2x-CommTxPoolNormal.
Else (UE is in RRC_IDLE),
Apply Random Selection using the pool indicated in v2x-CommTxPoolNormalDedicated, v2x-
CommTxPoolNormal or v2x-CommTxPoolExceptional.
Else
Apply Sensing based selection using the pool indicated in SL-V2X-Preconfiguration.

FIG. 5 is a flowchart illustrating aspects of theWTRU procedure500 for configuring NR V2X sidelink transmissions, e.g., as described with respect to Table 6. Although the above WTRU procedure considers the RRC connected mode and RRC idle mode, a similar procedure could be applied to RRC inactive mode. For example, the RRC inactive mode could be treated as RRC idle mode in the above procedure. Alternatively, the RRC inactive mode could be treated as RRC connected mode.

In theexemplary WTRU procedure500 for configuring NR V2X sidelink transmissions, if the WTRU is not in coverage on a frequency used forV2X sidelink communication510 or if the frequency used to transmit V2X sidelink communication is not included in v2x-InterFreqInfoList or v2x-InterRATInfoList520, the WTRU may perform sensing-based selection using pool in SL-V2X-Preconfiguration530. If, the WTRU is in coverage of bothV2X sidelink communication510 or if the frequency used to transmit V2X sidelink communication is included in v2x-InterFreqInfoList or v2x-InterRATInfoList520, the next step is determining whether the WTRU is inRRC_CONNECTED mode540. If the WTRU is not inRRC_CONNECTED mode540, then the WTRU performs random selection of sidelink transmission resources.550. If the WTRU is inRRC_CONNECTED mode540, the next step is to determine whether the WTRU is configured with commTxResources=scheduled560. If the WTRU is configured with commTxResources=scheduled, and there exists anexceptional condition570, then random selection is applied using pool v2x-CommTxPoolExceptional570(a). If there is noexceptional condition570, then the WTRU configures lower layers to request gNB570(b) to assign transmission resources for V2X sidelink communications. If the WTRU is not configured with commTxResources=scheduled560 and if the frequency for SL communication is in v2x-InterFreqInfoList580, then WTRU may use sensing based selection using pool in v2x-InterFreqInfoList580(a). If the frequency for SL communication is not in v2x-InterFreqInfoList580, then the WTRU may use sensing-based selection using pool v2x-InterRATInfoList580(b).

Some examples include dynamic scheduling of LTE sidelink and NR sidelink. In some examples, a single WTRU may be able to communicate on both LTE sidelink and NR sidelink. This example WTRU may be configured to be amode 3 UE for both LTE sidelink and NR sidelink, e.g., based on the NR V2X sidelink transmission procedures discussed above. Such WTRU may rely on the network to allocate the resources for its sidelink transmissions. In this example, the WTRU may be only under NR coverage (i.e., is only attached to and receiving signals from a NR gNB, not from an LTE eNB) and the gNB may dynamically schedule both the LTE sidelink and NR sidelink.

In some examples, the dynamic scheduling may be based on a unified DCI format for V2X. In some examples, the unified DCI format for V2X may include a field, which may be referred to as an NR Indicator field. The NR Indicator field may be used to indicate whether the current DCI is for the LTE sidelink grant or for the NR sidelink grant. In some examples, the NR Indicator field may include 1 bit, e.g., using the value of 1 to indicate that the current DCI is for the NR sidelink grant and using the value of 0 to indicate that the current DCI is for the LTE sidelink grant.

After receiving this DCI from NR gNB, the WTRU may first check the NR Indicator field of this DCI. If it is equal to 0 (for example), then the WTRU schedules the transmissions on LTE sidelink, using the grants from the remaining fields of the DCI. If the value is equal to 1 (for example), then the WTRU schedules the transmissions on NR sidelink, using the grants from the remaining fields of the DCI.FIG. 6 is a flow chart illustrating an exemplary (e.g., mode 3) procedure for a WTRU to determine whether to transmit using LTE sidelink transmissions or NR sidelink transmissions (i.e., to determine resource allocation for LTE sidelink or NR sidelink).

FIG. 6 illustrates anexemplary WTRU procedure600 of choosing between the LTE sidelink transmissions and the NR sidelink transmissions. After receiving the DCI fromNW610, the WTRU may check the field “NR Indicator” of theDCI620. If the “NR Indicator”620 is equal to a first value, such as 0, the WTRU may schedule the transmission on theLTE sidelink630, using the grants from the remaining fields of the DCI. If the “NR Indicator”620 is equal to a second value, the WTRU may schedule the transmissions on theNR sidelink640, using the grants from the remaining fields of the DCI.

In some examples, the dynamic scheduling may be based on separate DCI formats for NR sidelink and LTE sidelink. In such examples, the first type of DCI format may be for the legacy (i.e., LTE) sidelink resource allocation, while the second type of DCI format may be for the NR sidelink resource allocation.

These two types of DCI formats may have different payload sizes. In some examples, blind detection is used to distinguish between these two DCI formats. For blind detection, we assume one of the DCI formats is used and apply the corresponding coding, since we do not know which DCI format is used. If the decoding is successful (i.e., CRC check passes) then we know the assumed DCI format is correct. Otherwise, we assume the other DCI format is used and apply the corresponding decoding. These two types of DCI formats may have the same payload size, where a different RNTI may be used for the CRC mask. In some examples, if using the RNTI for LTE sidelink service passes the CRC check, then the DCI format is for LTE sidelink. If using the RNTI for NR sidelink service passes the CRC check, then the DCI format is for NR sidelink.

In some cases, the V2X sidelink communication configurations may be different between a LTE cell and a NR cell. For example, the SL-CommResourcePoolV2X-r16 IE for NR V2X may configure the size of sub-channels in terms of resource blocks, the total number of sub-channels in the resource pool N_subchannel^SL, etc. These sizes may be different from SL-CommResourcePoolV2X IE for LTE V2X. Accordingly, the DCI field sizes of the “Lowest index of sub-channel allocation to initial transmissions” or “Frequency resource location of initial transmission and retransmissions” could be different from LTE cell and NR cell as well.

FIG. 7 illustrates anexemplary message exchange700 between aWTRU710 and aneNB720 or agNB730. TheWTRU710 may receive SIB21721 for the LTE V2X sidelink communication common fromeNB720. TheWTRU710 then may sendSidelinkUEInformation722 back to theeNB720. TheWTRU710 may receive the RRCConnectionReconfiguration and transmit the RRCConnectionReconfigurationComplete.723 for the LTE V2X sidelink communication dedicated configurations. Based on the configurations, theWTRU710 may be amode 3 WTRU and it may receive the dynamic resource allocation viaDCI 5A724 in LTE. TheWTRU710 may move out of theLTE eNB720 coverage and into theNR gNB730 coverage. TheWTRU710 may receive theSIB V2X731 fromgNB730 for NR V2X sidelink communication common configurations. TheWTRU710 may sendSidelinkUEInformation732 to thegNB730 showing interest in the sidelink transmission. TheWTRU710 may receive and transmit theRRCConnectionReconfiguration733 for the sidelink communication dedicated configurations. TheWTRU710 may receive the dynamic resource allocation via DCI 3_0734.

FIG. 7 illustrates example message exchanges between a WTRU and an eNB or gNB. In this example, the WTRU is moving from LTE coverage to NR coverage. Initially, the WTRU is camped on LTE eNB. The WTRU receives a SIB21 for LTE V2X sidelink communication common configurations, or it receives RRCConnectionReconfiguration for LTE V2X sidelink communication dedicated configurations. The WTRU sends sidelinkUEInformation to eNB, indicating that it is interested in performing LTE V2X sidelink transmissions and requests assignment of transmission resources. Based on the configuration, the WTRU is amode 3 WTRU and receives the dynamic resource allocation viaDCI 5A in LTE. Thereafter, the WTRU applies the allocated resources for its transmissions.

After some time, this WTRU moves out of LTE eNB coverage and into NR gNB coverage. The WTRU receives the SIB-V2X from gNB for NR V2X sidelink communication common configurations or receives the RRCConnectionReconfiguration for the NR V2X sidelink communication dedicated configurations. It sends sidelinkUEInformation to gNB, showing that it is interested in the LTE V2X sidelink transmissions and requests the assignment of transmission resources. The UE may receive the dynamic resource allocation via a DCI format in NR and decode it using the RNTI associated with LTE sidelink service, or it may receive the dynamic resource allocation via a unified DCI format with the “NR Indicator” field being 0. Then it applies the allocated resources to continue its LTE sidelink transmissions.

FIG. 8 is a flow chart which illustrates anexample procedure800 for a WTRU to move from LTE eNB coverage to NR gNB coverage while maintaining LTE sidelink transmissions. The WTRU may receiveLTE sidelink configurations810. The WTRU may then receiveLTE DCI 5A forSL resource allocation820. Then, the WTRU receives NR sidelinkconfigurations830. The WTRU then receives NR DCI forSL resource allocation840. Then the WTRU determines whether the DCI is forLTE sidelink grant850. If the DCI is for LTE sidelink grants, the WTRU continues to use allocated resources for LTE-basedSL transmission860, but if the WTRU is not for LTE sidelink grant, then the WTRU uses allocated resources for NR-basedSL transmissions870.

Some embodiments include NR Uu enhancement for unicast and group-cast sidelink. In anexample mode 3 WTRU, a gNB allocates resources for the sidelink transmissions. In LTE, the sidelink transmissions are via broadcast, and no feedback from the receiving WTRU is needed. In NR, the sidelink transmissions may be unicast or group-cast. For example, two vehicles, traveling one in front and one behind, may communicate with each other. The front vehicle may send road conditions to the back vehicle. In this scenario, HARQ feedback from the back vehicle to the front vehicle may be needed.

Accordingly, it may be desired to support resource allocation for unicast and group-cast communications which need HARQ feedback from the receiving WTRU to enhance reliable transmissions.

In this example, if the front vehicle is amode 3 WTRU, it may request resources needed for the unicast or group-cast sidelink transmissions from the gNB. In this resource allocation request, the transmitting WTRU may request not only the resources for the data transmissions, but also resources for the HARQ feedback from the back vehicle. To support this feature, a new NR DCI format may also need to reserve the HARQ-ACK resource, as well as the data transmission resource. Accordingly, in some examples, an additional item is added to the NR DCI format. This item may be referred to as “PSSCH-to-HARQ feedback timing” for example. This field may provide a time gap between data transmission (or the last data retransmission of the transport block if there are data retransmissions) and HARQ feedback. This field may contain 1, 2, or 3 bits, for example, to indicate up to a 2, 4 or 8 slot time gap respectively.

In addition to a time-domain resource reservation for the HARQ feedback, frequency domain resources should also be reserved for the HARQ feedback. Accordingly, an additional field may be introduced into the NR DCI format. This field may be referred to as “sub-channel allocation for HARQ” for example. In some examples, the same sub-channel as the initial transmission for the HARQ feedback. Then the “sub-channel allocation for HARQ” field could be one bit indication. In some examples, either the same sub-channel as the initial transmission or as the retransmission may be used for the HARQ feedback. In such cases, the “sub-channel allocation for HARQ” field may be a two-bit indication. In some examples, the sub-channel index of the HARQ feedback may be explicitly indicated. In such cases, the “sub-channel allocation for HARQ” field may be ┌log₂N_subchanne^SL┐ bits in length. In some examples, another resource in another resource pool different from the PSSCH resource pool may be explicitly indicated.

If the transmitting WTRU sends the unicast or group-cast data with sidelink control information (SCI), the SCI could contain the timing gap information. This may be done to reserve the resources for the HARQ feedback transmissions. In other words, besides the field which may be referred to as a “time gap between initial transmission and retransmission” field in NR SCI, there may be an additional field, which may be referred to as a “time gap between last (re)transmission and feedback” in NR SCI. Similarly, the NR SCI could also contain frequency domain reservation information for the HARQ, in a similar scheme as for NR DCI. Here, the resource for HARQ feedback transmissions may not have to be of the same size as the resource for data transmissions. The resource for HARQ feedback transmissions may be in the same pool as the resource for data transmissions. The resource for HARQ feedback transmissions may be in a different pool as the resource for data transmissions.

The receiving WTRU may try to decode the unicast and group-cast data and send the HARQ on this reserved resource.

In anexample mode 3 WTRU procedure for sending unicast or group-cast sidelink data, a transmitmode 3 WTRU first send a scheduling request to gNB. After the UL grant is received, themode 3 WTRU sends a buffer status report (BSR) with an indication that the data is for unicast or group-cast. Based on the BSR, the gNB may assign resources for the WTRU to transmit unicast or group-cast sidelink transmissions. The transmitmode 3 WTRU then applies the first assigned resources for its sidelink data transmissions. After sending the sidelink data in the assigned resource pool, the transmitmode 3 WTRU may receive HARQ feedback in the assigned resources from the gNB.

FIG. 9 is a flow chart illustrating anexample procedure900 for sending unicast or group-cast sidelink data. A transmitmode 3 WTRU may send a scheduling request to agNB910. The WTRU may then receive the UL grant from the gNB to send a buffer status report (BSR)920. The WTRU may send the BSR to the gNB, with an indication that the data is for unicast or group-cast SL transmissions930. The WTRU may then receive from the gNB an SL grant with assigned resource for both data transmissions andHARQ feedback940. The WTRU may then transmit SL unicast or groupcast data on the assignedresource950. The WTRU may thereafter receive HARQ from other WTRUs on the assignedresource960.

Some embodiments include a configured grant for NR sidelink. In LTE V2X, up to 2 repetitions of the same transport block (TB) are supported for sidelink transmissions. For amode 3 WTRU, the network may simultaneously assign the resources for 2 repetitions. In NR, up to 8 repetitions of the same TB are supported for uplink transmissions. Accordingly, it may be desired to support multiple numbers of repetitions of the same TB for sidelink grant-free configuration, e.g., using methods, procedures, and IE signaling described below.

In some examples, UL configuredgrant type 1 ortype 2 schemes could be applied to sidelink transmissions. In some examples,type 1 grants are withoutlayer 1 activation/deactivation, andtype 2 are withlayer 1 activation/deactivation. To support multiple repeated transmissions of the same TB in a sidelink configured grant, it may be desired to also configure the number of repetitions. In some examples, the number of repetitions may be associated with the configured grant. Further, the redundancy version (RV) may vary in different repetitions. Accordingly, it may be beneficial to configure the RV of the repetition in the sidelink configured grant. For example, a new IE, which may be referred to as BWP-SidelinkDedicated, may be defined as follows in Table 7. Thesidelink grant type 1 orsidelink grant type 2 may be configured based on WTRU capabilities.

TABLE 7

BWP-Sidelink ::=	SEQUENCE {

	bwp-Dedicated	BWP-SidelinkDedicated
	...

}
BWP-SidelinkDedicated ::=	SEQUENCE {

configuredSidelinkGrantConfig

SetupRelease { ConfiguredSidelinkGrantConfig }

...

}
ConfiguredSidelinkGrantConfig ::=	SEQUENCE {
...

	repK
	repK-RV
	rrc-ConfiguredSidelinkGrant	SEQUENCE {
	...
	}

}

Although the sidelink configured grant may configure the number of repetitions of the same TB, this number may be dynamically changed due to the number of resources available in the resource pool. The DCI format, which activates the sidelink configuredgrant type 2, may grant a different number of resources from the configured value. In this case, the WTRU may apply the dynamically indicated number of resources for the repetition. If the dynamically indicated number of resources matches the configured number of repetitions, the RV of the repetition may follow the configured pattern. If the dynamically indicated number of resources does not match the configured number of repetitions, the indicated number of resources may be the number of repetitions and the RV of the repetition may depend on WTRU's decision, or may follow a different pattern from the configured RV pattern.

FIG. 10 is a flow chart illustrating an example of such aWTRU procedure1000 for determining the number of repetitions and its associated RV pattern in the sidelink configuredgrant type 2. The WTRU may receive the SL configured grant configuration1010. The WTRU then receives the DCI to activate the SPS transmission, with a certain number of resources forSL data transmission1020. It must then be determined whether the number of resources in DCI matches the configured number ofrepetitions1030; if yes, then apply the configured number of repetitions with the associatedRV pattern1040, and if no, then apply the indicated number of repetitions with adifferent RV pattern1050.

Some embodiments include handling of multiple MCS tables. In Release 14 LTE V2X, a single MCS table is used, limited to quadrature phase shift keying (QPSK) and 16 point quadrature amplitude modulation (16QAM). In Release 15 LTE V2X, the same MCS table is used without this limitation. The MCS entry based on the given MCS table may be configured in the IEs of SL-PSSCH-TxParameters, SL-CommConfig, SL-V2X-ConfigDedicated.

For NR URLLC use cases, there are two available MCS tables for cyclic prefix OFDM (CP-OFDM), i.e., MCS table 1 and MCS table 3. MCS table 1 has a relatively high spectral efficiency entries working mainly for the block error rate (BLER) target of 10⁻¹, while MCS table 3 has a relatively low spectral efficiency entries working mainly for the BLER target of 10⁻⁵.

Since NR V2X includes a type of URLLC use cases having a lowest reliability requirement of 1-10⁻⁵, it is feasible to apply two MCS tables to V2X. Accordingly, in some examples the MCS table may be configured for NR V2X transmissions. For amode 3 WTRU, both MCS table index and MCS entry index may be configured. The configuration may be for the IE of SL-V2X-ConfigDedicated as follows. An example implementation of SL-V2X-ConfigDedicated appears in Table 8. In the “scheduled” component, two fields could be added. Such fields may be referred to as “mcs-Table” field and “mcs-Entry” field. In some examples, the values for the mcs-Table field could be “lowSE” indicating the configured MCS table is MCS table 1; or could be “highSE” indicating the configured MCS table is MCS table 3. Any suitable naming is possible. In some examples, if these two fields are not configured, the selection of MCS table and MCS entry may be left to WTRU implementation. In some examples, configuring only the “mcs-Table” field while leaving “mcs-Entry” field not configured may be possible. In such cases, the WTRU is permitted, but not required, to select the MCS index within the configured MCS table.

	TABLE 8

	SL-V2X-ConfigDedicated ::=	SEQUENCE {
	commTxResources	CHOICE {
	release	NULL,
	setup	CHOICE {
	scheduled	SEQUENCE {
	......
	mcs-Table	ENUMERATED{lowSE, highSE}
	mcs-Entry
	},
	......
	}

The IE SL-PSSCH-TxParameters configures the minimum and maximum MCS values used for transmissions on PSSCH. These parameters may depend on the MCS tables. Accordingly, we may define maximum and minimum MCS values for each MCS table. For example, two values, which may be referred to as “minMCS-PSSCH-lowSE” and “maxMCS-PSSCH-lowSE” may be used to define minimum and maximum MCS values for MCS table 1, while two other values, which may be referred to as “minMCS-PSSCH-highSE” and “maxMCS-PSSCH-highSE” may be used to define minimum and maximum MCS values for MCS table 3. Table 9 shows an example SL-PSSCH-TxParameters IE:

	TABLE 9

	SL-PSSCH-TxParameters ::=	SEQUENCE {
	minMCS-PSSCH-lowSE	INTEGER (0..31),
	maxMCS-PSSCH-lowSE	INTEGER (0..31),
	minMCS-PSSCH-highSE	INTEGER (0..31),
	maxMCS-PSSCH-highSE	INTEGER (0..31),
	......
	}

The discussions above relate to the CP-OFDM waveform. It is noted that the same approaches may also be applied to the DFT-S-OFDM waveform.

MCS table selection and MCS index selection may be dynamically indicated. In some examples, the MCS table selection and MCS index selection may be indicated to the receiving WTRU via explicit SCI contents from the transmitting WTRU. In some examples, the SCI may include a new field, which may include a single bit. This field may be referred to as “MCS table selection.” If this field is 0 (for example), then the MCS table 1 is selected. Otherwise, the MCS table 3 is selected. Another way to distinguish the MCS table selection is to use different RNTI's to scramble CRC of the SCI. In some examples, if a new RNTI is used to scramble CRC of the SCI, then MCS table 3 is used. Otherwise, the MCS table 1 is used.

In some examples, the MCS table selection can be indicated in association with (e.g., by) the PSCCH resource locations. In some examples, the starting sub-channel index of the PSCCH/PSSCH may be used to distinguish the MCS table selection. For example, if the starting sub-channel index is below a certain number (e.g., 10) then the MCS table 1 is used. Otherwise, the MCS table 3 is used.

In some examples, MCS table selection can be indicated in association with (e.g., by) the communication resource pools. In some examples, each communication resource pool may support only a single MCS table. In some examples, the WTRU may automatically switch the MCS table by switching its communication resource pool.

In some examples, the MCS table selection is liked with the data PPPR value. In some examples, the data PPPR value may be introduced in SCI. For example, for data with requirements for greater reliability (e.g., PPPR is less than a threshold), the MCS table containing low spectrum efficiency entries (e.g., MCS table 3) will be used. Otherwise, the other MCS table (e.g., MCS table 1) will be used.

In some examples, the MCS table selection can be distinguished by applying the RNTI to only some of the the CRC bits for SCI. For example, the RNTI may be 16 bits and the CRC may be 24 bits. Note that it is possible that the first 7 CRC bits may be distributed for early termination of the SCI decoding. Accordingly, the last 17 CRC bits are always appended. For example, if MCS table 1 is selected, then the RNTI is used to mask the last 16 CRC bits. If MCS table 3 is selected, then the RNTI is used to mask the second last CRC bit to the 17th last CRC bit.

FIG. 11 is abitmap1100 illustrating an example CRC mask with RNTI on different CRC bits to indicate which MCS table is used. If there are more than 17 CRC bits not distributed or appended, then the parts of the appended CRC bits to be masked with RNTI could have different choices to indicate the used MCS table. The techniques discussed above may be extended to distinguish more than 2 MCS tables, e.g., if more than 2 MCS tables are allowed to be used for V2X communication.

More specifically, if the MCS table 11110 is used, the RNTI may be used to mask the last 16CRC bits1120. If instead the MCS table 31130 is used, the RNTI may be used to mask the 2^ndlast CRC bit to the 17thlast CRC bit1140.

FIG. 12 is a flow chart illustrating an example of theoverall SCI procedure1200, of which the CRC mask operations illustrated with respect toFIG. 11 may be a part. The procedure begins first withCRC attachment1210. Then the MCS table may be selected, and CRC masking may occur 1220. This is followed by polar encoding 1230, then rate matching1240, and finally scrambling1250.

Some embodiments include establishing group-cast or unicast sidelink. In LTE V2X, the sidelink is only broadcast. Group-cast or unicast sidelink may be supported in NR V2X. Various methods, devices, and systems may be implemented to support establishment of group or direct (one-to-one) communication. In some examples, the case of unicast sidelink communication may be conceptualized as a group-cast sidelink communication with group size being 2.

An example use scenario for group-cast or unicast sidelink can be referred to as vehicle platooning. All the vehicles in a platoon may seek to have group based communication. Further, any particular vehicle in a platoon may want to communicate with the platoon leader (e.g., the vehicle in the front of the platoon).

The group for sidelink may be established with the help of (e.g., may be coordinated by) gNB. This may be achieved by modifying the Uu link, as well as the sidelink.FIG. 13 is a message sequence chart illustrating an example flow for establishing a communication group.

FIG. 13 illustrates an exemplary flow diagram1300 for establishing a sidelink communication group. In this example,WTRU 11310 andWTRU 21320 may be within the coverage of thegNB1330.WTRU 11310 andWTRU 21320 may receive systeminformation SIB V2X1340 from thegNB1330. Thereafter,WTRU 1 may exchange a RRCConnectionReconfiguration1350 (a) message with thegNB1330. In this message exchange,WTRU 11310 may register to transmit Sidelink Synchronization Signal/Physical Sidelink Broadcast Channel (SLSS/PSBCH)1360 and to be a group head.WTRU 21320 may receive the SLSS and MIB-SL-V2X1370.WTRU 21320 may be interested in joining thegroup communication1380 withWTRU 11310.WTRU 21320 does this by exchangingRRCConnectionReconfiguration1390 with thegNB1330.

In the example ofFIG. 13, a first WTRU (UE 1) and a second WTRU (UE 2) are within the coverage of the gNB. UE1 and UE2 receive system information SIB V2X from gNB. Thereafter,UE 1 exchanges a RRCConnectionReconfiguration message with gNB. In this message exchange,UE 1 registers to transmit Sidelink Synchronization Signal/Physical Sidelink Broadcast Channel (SLSS/PSBCH) and also registers to be a group head.

In some examples, RRCConnectionReconfiguration includes SL-V2X-ConfigDedicated, IE, which may include a group control field which may include fields for “message-type,” “SLSS-ID,” “group-ID,” “group-head,” and “group-members.” SinceUE 1 is the group head and registers for a new group, the “message-type” could be of value “create.” The “SLSS-ID” indicates an SLSS-ID to be used byUE 1 for its broadcast SLSS/PSBCH message. This value may be derived from the configuration. The “group ID” could be assigned by gNB. The “group-head” could be some identity ofUE 1. At this stage, the “group-members” field could be empty as there are no other members in the group. Table 10 lists an example of SL-V2X-ConfigDedicated:

TABLE 10

SL-V2X-ConfigDedicated ::= SEQUENCE {
group-control SEQUENCE {
message-type ENUMERATED {create, join, leave, remove}
SLSS-ID
group-ID
group-head
group-members
}
...
}

UE 2 may receive the SLSS and MIB-SL-V2X fromUE 1. UE2 may be interested in joining the group communication withUE 1. Accordingly, UE2 exchanges a RRCConnectionRecofiguration message with the gNB. In the IE SL-V2X-ConfigDedicated, the gNB may set “message-type=join,” and the SLSS ID as the detected SLSS ID fromUE 1. The gNB may send the IE SL-V2X-ConfigDedicated toUE 2, with the associated group ID, group head and group members information toUE 2. gNB may also update the group information with the group head (i.e., UE 1).

IfUE 2 wants to leave the group, it may send the IE SL-V2X-ConfigDedicated to gNB with “message-type=leave” and the proper SLSS ID. gNB may confirm and update the group information with thegroup head UE 1.

If UE1 wants to remove the group, it may send the IE SL-V2X-ConfigDedicated to gNB with “message-type=remove” and the proper SLSS ID. gNB may confirm and update the group information with all the group members.

In the example scheme above, the group ID is exchanged between individual WTRUs and gNB. A group member WTRU may find the proper group by providing the SLSS ID to gNB. Alternatively, the group ID information may be directly sent out in SLSS/PBSCH. For example, the MIB-SL-V2X sent byUE 1 may contain a “group-ID” field. This ID may be used for other UEs to establish the group communication with the UE sending the SLSS and MIB-SL-V2X. Table 11 illustrates the example group-ID field:

	TABLE 11

	MasterInformationBlock-SL-V2X::= SEQUENCE {
	......
	Group-ID
	}

In this scheme, the “SLSS ID” field in the IE SL-V2X-ConfigDedicated may be ignored.UE 2 may directly inform gNB about the group ID it wants to join to leave. Although e introduce the group-control parameters are described with respect to the SL-V2X-ConfigDedicated IE for the sake of example, it is not restricted to this IE.

Although the features and elements of the present invention are described in the preferred embodiments in particular combinations, each feature or element can be used alone without the other features and elements of the preferred embodiments or in various combinations with or without other features and elements of the present invention.

Although the solutions described herein consider New Radio (NR), 5G or LTE, LTE-A specific protocols, it is understood that the solutions described herein are not restricted to this scenario and are applicable to other wireless systems as well.

Although features and elements are described above in particular combinations, one of ordinary skill in the art will appreciate that each feature or element can be used alone or in any combination with the other features and elements. In addition, the methods described herein may be implemented in a computer program, software, or firmware incorporated in a computer-readable medium for execution by a computer or processor. Examples of computer-readable media include electronic signals (transmitted over wired or wireless connections) and computer-readable storage media. Examples of computer-readable storage media include, but are not limited to, a read only memory (ROM), a random access memory (RAM), a register, cache memory, semiconductor memory devices, magnetic media such as internal hard disks and removable disks, magneto-optical media, and optical media such as CD-ROM disks, and digital versatile disks (DVDs). A processor in association with software may be used to implement a radio frequency transceiver for use in a WTRU, UE, terminal, base station, RNC, or any host computer.