CN110536429B - Through link beam management method, device, equipment and readable storage medium - Google Patents

Abstract

The embodiment of the invention provides a through link beam management method, a device, equipment and a readable storage medium, which are used for acquiring through link beam failure recovery configuration information, and then performing beam failure recovery processing according to the acquired through link beam failure recovery configuration information, so that when through link beam failure occurs in a through link unicast communication or other communication processes, through link beam recovery can be performed in time to ensure service continuity and improve system performance.

Description

Through link beam management method, device, equipment and readable storage medium

Technical Field

The embodiments of the present invention relate to, but are not limited to, the field of communications, and in particular, but not limited to, a method, an apparatus, a device, and a readable storage medium for direct link beam management.

Background

The vehicle networking refers to a large system network for wireless communication and information exchange between vehicles-X (X: vehicles, pedestrians, roadside equipment, the Internet and the like) according to an agreed communication protocol and a data interaction standard. The vehicle can obtain safe driving, high traffic efficiency and convenient or entertainment information through the Internet of vehicles communication. Classified from the objects of wireless communication, internet of vehicles communication includes three different types: vehicle-to-Vehicle communication (V2V for short), vehicle-to-Infrastructure/Vehicle-to-Network communication (V2I/V2N for short), and Vehicle-to-Pedestrian communication (V2P for short), collectively referred to as V2X communication.

In the study of LTE (Long Term Evolution) based V2X communication organized by 3GPP (3 rd Generation Partnership Project), a V2X communication method based on a direct link (also referred to as a sidelink link) between User equipments (users, abbreviated as UEs) is one of ways implemented by the V2X standard, that is, service data is not forwarded through a base station and a core network, as shown in fig. 1, UE1 directly transmits service data to UE2 through an air interface (an interface introduced in 3GPP Rel-12 for direct interaction between UE and UE, referred to as a PC5 interface), or UE3 directly transmits service data to UE1 through an air interface, and such a V2X communication mode may be abbreviated as PC5-based V2X communication or V2X sidelink communication.

With the technological progress and the development of automation industry, the V2X communication scenario is further extended and has higher performance requirements. The 3GPP has already established research on car networking communication based on fifth Generation mobile communication technology (5g, 5th Generation), including car networking communication based on a 5G air interface and car networking communication based on a 5G direct link (NR sidelink). The 5G direct link communication can support broadcast, multicast and unicast communication; when the 5G direct link communication adopts the unicast communication, if the unicast communication has a direct link beam failure (also referred to as a direct link beam failure) sidelink beam failure, the communication service may be interrupted. Therefore, when the through link beam fails in unicast communication, how to recover the through link beam to ensure service continuity is a technical problem that needs to be solved urgently at present.

Disclosure of Invention

The embodiment of the invention provides a method, a device, equipment and a readable storage medium for managing a through link beam, which mainly solve the technical problems that: how to perform the recovery of the through link beam when the through link beam fails.

In order to solve the above problem, an embodiment of the present invention provides a through link beam management method, including:

acquiring direct link beam failure recovery configuration information;

and according to the acquired through link beam failure recovery configuration information, performing beam failure recovery processing.

In order to solve the above problem, an embodiment of the present invention further provides a through link beam management method, including:

receiving a beam failure recovery processing message sent by opposite terminal UE;

and performing beam failure recovery processing according to the beam failure recovery processing message.

In order to solve the above problem, an embodiment of the present invention further provides a direct link beam management apparatus, including:

the first information acquisition module is used for acquiring the beam failure recovery configuration information of the straight-through link;

and the first processing module is used for carrying out beam failure recovery processing according to the acquired beam failure recovery configuration information of the through link.

In order to solve the above problem, an embodiment of the present invention further provides a through link beam management apparatus, including:

a second information acquisition module, configured to receive a beam failure recovery processing message sent by an opposite-end UE;

and the second processing module is used for carrying out beam failure recovery processing according to the beam failure recovery processing message.

In order to solve the above problem, an embodiment of the present invention further provides a user equipment, including a first processor, a first memory, and a first communication bus;

the first communication bus is used for realizing communication connection between the first processor and the first memory;

the first processor is configured to execute one or more first programs stored in the first memory to implement the steps of the through-link beam management method as described above.

In order to solve the above problem, an embodiment of the present invention further provides a user equipment, including a second processor, a second memory, and a second communication bus;

the second communication bus is used for realizing communication connection between the second processor and the second memory;

the second processor is configured to execute one or more second programs stored in the second memory to implement the steps of the through-link beam management method as described above.

In order to solve the above problem, embodiments of the present invention also provide a computer-readable storage medium storing one or more first programs, which are executable by one or more processors to implement the steps of the through-link beam management method as described above;

or the like, or a combination thereof,

the computer readable storage medium stores one or more second programs, which are executable by one or more processors to implement the steps of the through-link beam management method as described above.

The invention has the beneficial effects that:

according to the through link beam management method, the through link beam management device, the through link beam management equipment and the readable storage medium provided by the embodiment of the invention, through link beam failure recovery configuration information is obtained first, and then beam failure recovery processing is carried out according to the obtained through link beam failure recovery configuration information, so that when through link beam failure occurs in unicast communication or other communication processes, through link beam recovery can be carried out in time to ensure service continuity, and the reliability of a system is improved.

Additional features and corresponding advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

FIG. 1 is a diagram of a communication system architecture;

fig. 2 is a schematic flow chart of a direct link beam management method on a source UE side according to a first embodiment of the present invention;

fig. 3 is a schematic flowchart of a direct link beam management method at a target UE side according to a first embodiment of the present invention;

fig. 4 is a schematic flow chart of a beam reconfiguration processing procedure at a source UE side according to a second embodiment of the present invention;

fig. 5 is a flowchart illustrating a beam reconfiguration processing procedure at a target UE side according to a second embodiment of the present invention;

fig. 6 is a flowchart illustrating a process of establishing unicast communication under Model a according to a third embodiment of the present invention;

fig. 7 is a flowchart illustrating a process of establishing unicast communication under Model B according to a third embodiment of the present invention;

fig. 8 is a schematic view of an interaction flow of the Sidelink beam failure recovery configuration information according to the third embodiment of the present invention;

fig. 9 is a schematic diagram illustrating a flow of performing beam failure recovery in a first mode according to a third embodiment of the present invention;

FIG. 10 is a flowchart illustrating an authorization verification process according to a fourth embodiment of the present invention;

FIG. 11 is a flowchart illustrating another authorization verification process according to a fourth embodiment of the present invention;

fig. 12 is a schematic structural diagram of a direct link beam management apparatus according to a fifth embodiment of the present invention;

fig. 13 is a schematic structural diagram of another direct link beam management apparatus according to a fifth embodiment of the present invention;

fig. 14 is a schematic structural diagram of a ue according to a sixth embodiment of the present invention;

fig. 15 is a schematic structural diagram of another ue according to a sixth embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention are described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.

The first embodiment is as follows:

in order to reduce the possibility of service interruption caused by occurrence of a sidelink beam failure in the unicast communication or other types of communication as much as possible, the method for managing a straight-through link beam provided in this embodiment may first acquire sidelink beam failure recovery configuration information (i.e., sidelink beam failure recovery configuration information), and may further perform beam failure recovery processing according to the acquired sidelink beam failure recovery configuration information, so that when a straight-through link beam failure occurs in the unicast communication or other types of communication, recovery of a straight-through link beam is performed as soon as possible to ensure service continuity.

Alternatively, in this embodiment, it may be set that only one UE performs direct link beam management (e.g., performs sidelink beam failure recovery) for the user equipments UEs at both sides of communication in direct link communication, or it may be set that either UE performs direct link beam management. For convenience of understanding, in this embodiment, a UE on a party initiating direct link beam management (e.g., sidelink beam failure recovery) may be referred to as a source UE, and a UE on a communication opposite end of the source UE is referred to as a target UE. For example, still illustrated in the application scenario shown in fig. 1. For two communication parties UE1 and UE2 of the direct link communication in fig. 1, when UE1 executes direct link beam management, UE1 is a source UE, and UE2 at the opposite end is a target UE; when UE2 performs direct link beam management, UE2 is the source UE, and UE1 at the opposite end is the target UE. Of course, in some examples, it is not excluded that UEs (e.g., UE1 and UE 2) of both communication parties perform direct link beam management simultaneously, where UE1 is a source UE, UE2 is a target UE, UE2 is also a source UE, and UE1 is also a target UE.

And it should be understood that the UE in this embodiment may be any user equipment capable of performing sidelink communication, including but not limited to a user terminal, various vehicle-mounted terminals on a vehicle, and other communication terminals outside the vehicle (including but not limited to a roadside, a parking spot, a gas station, a charging station, etc.) capable of communicating with the user terminal and/or the vehicle-mounted terminal.

For ease of understanding, the present embodiment is exemplified below with direct link beam management methods of a source UE side and a target UE side, respectively.

For the source UE side, the direct link beam management method thereof is shown in fig. 2, and may include but is not limited to:

s201: and acquiring the direct link beam failure recovery configuration information.

It should be understood that the acquisition of the through-link beam failure recovery configuration information in the present embodiment is not acquired in real time every time the through-link beam failure recovery is performed. In some examples, the through-link beam failure recovery configuration information may be obtained only once and saved after the obtaining for use in through-link beam failure recovery. In some examples, after the direct link beam failure recovery configuration information, when the direct link beam failure recovery configuration information is updated, the updated direct link beam failure recovery configuration information is obtained again for use in direct link beam failure recovery.

In this embodiment, the manner of obtaining the direct link beam failure recovery configuration information may be flexibly set, for example, in an example, the direct link beam failure recovery configuration information may be obtained through at least one of the following manners:

the method I comprises the following steps: acquiring straight-through link beam failure recovery configuration information from a base station;

in this embodiment, the direct link beam failure recovery configuration information may be obtained through Radio Resource Control (RRC) communication information, which includes but is not limited to, that is, the base station may send the direct link beam failure recovery configuration information to the UE through various RRC communication information.

The second method comprises the following steps: acquiring direct link beam failure recovery configuration information from User Equipment (UE) of a communication opposite end;

as can be seen from the above analysis, in this embodiment, the UE of the correspondent node is the target UE. In an example, the target UE may send the direct link beam failure recovery configuration information to the source UE actively or according to a request of the source UE. The interaction of the direct link beam failure recovery configuration information between the source UE and the target UE may be performed through, but not limited to, at least one of the following messages:

PC5 connection establishment message (or called PC5 connection request message), PC5 connection establishment response message, PC5 bearer configuration response message, PC5 reconfiguration message, and direct link beam failure recovery configuration message (i.e. sidelink beam failure recovery configuration message).

The third method comprises the following steps: acquiring straight-through link beam failure recovery configuration information from the pre-configuration information;

it should be understood that, in this mode, the pre-configuration information may be configured directly on the UE, or may be configured on other devices dedicated to configuring the direct link beam failure recovery configuration information for the UE.

S202: and according to the acquired straight-through link beam failure recovery configuration information, performing beam failure recovery processing.

In this embodiment, performing the beam failure recovery processing according to the acquired through link beam failure recovery configuration information includes:

and according to the through link beam failure recovery configuration information, when detecting that the through link beam failure recovery condition is triggered, executing a through link beam failure recovery process, wherein the process comprises the step of sending a beam failure recovery processing message to the opposite terminal UE for beam recovery processing.

In one example of this embodiment, the through link beam failure recovery configuration information may include, but is not limited to, at least one of:

whether to synchronize source UE indication information, supported direct link sidelink discovery mode indication information, a beam failure detection resource (i.e. beam failure detection resource), a beam failure detection timer (i.e. beam failure detection timer), a maximum beam failure instance number (i.e. maximum beam failure instance number), a candidate beam resource (i.e. candidate beam resource), a beam failure recovery timer (i.e. beam failure recovery timer), a beam failure recovery request retransmission timer (i.e. beam failure recovery request retransmission timer), a beam failure recovery request retransmission maximum number (i.e. beam failure recovery request retransmission maximum number), a beam failure recovery maximum number (i.e. beam failure recovery maximum number), and a beam quality threshold (i.e. beam quality threshold).

It should be understood that, in this embodiment, the through link beam failure recovery configuration information may specifically include which information of the above information is included, and how the included information is used in combination, and may be flexibly selected according to a specific application scenario.

In one example of this embodiment, the candidate beam resources may include, but are not limited to, at least one of:

beam index (i.e., beam index), direct link synchronization reference signal (i.e., sidelink synchronization reference signal), direct link discovery signal (i.e., sidelink discovery signal), direct link communication channel measurement signal, dedicated direct link beam measurement signal (i.e., signal dedicated to sidelink beam detection), direct link synchronization resource (i.e., sidelink synchronization resource), direct link communication resource (i.e., sidelink communication resource for use in sidelink communication), direct link discovery resource (i.e., sidelink discovery resource), beam failure recovery dedicated resource (i.e., beam failure recovery dedicated resource, which may be configured as a resource for specified use in this embodiment, including but not limited to beam resource), beam failure recovery contention resource pool (i.e., beam failure contention resource pool, which in this embodiment is configured as a resource in the beam failure contention resource pool, which may be shared by at least two UEs, including but not limited to beam resource.

For ease of understanding, the present embodiment is described below with an example of detecting whether a through link beam failure recovery condition is triggered.

In this embodiment, the failure of the through-link beam refers to the condition that the quality of the through-link beam has reached the condition that normal communication cannot be performed. The value setting of the threshold value for specifically judging whether the communication can be performed normally can be flexibly set based on factors such as specific communication reliability requirements, communication environments and the like.

In this embodiment, the triggering of the through link beam failure recovery condition may be triggered as soon as the currently used beam is detected to be failed, or may be triggered when the currently used beam is detected to be failed and the failure condition meets a preset failure condition. The specific predetermined failure condition should be understood to be flexibly configurable.

That is, in this embodiment, detecting whether the through link beam failure recovery condition is triggered may include: it is detected whether the currently used beam is failed.

In this embodiment, a method for detecting the beam quality is provided, and the quality detection result may be optionally used as a basis for determining beam failure (the determination of beam failure may also adopt other determination methods), as a basis for selecting a beam, or as a basis for determining whether a beam needs to be reconfigured, and the like, and may be flexibly selected according to specific requirements.

The beam quality measurement method provided by this embodiment includes, but is not limited to, at least one of the following methods:

the first method is as follows: the discovery signal is subject to quality measurements including, but not limited to:

receiving a direct link discovery announcement message sent by opposite terminal UE, measuring beam quality according to the received direct link discovery announcement message, and specifically measuring the quality of a beam receiving the direct link discovery announcement message;

sending a direct link discovery request message to opposite terminal UE, receiving a direct link discovery response message sent by the opposite terminal UE, and measuring the quality of a wave beam required to be measured according to the received direct link discovery response message;

the second method comprises the following steps: when the synchronization source UE is determined to be needed according to the indication information of whether the synchronization source UE exists, receiving a direct link synchronization reference signal sent by the opposite end UE to carry out beam quality measurement;

in this way, the UE at the opposite end may periodically send a direct link synchronization reference signal, and the UE at the home end may measure the quality of the beam currently required to be measured according to the direct link synchronization reference signal sent by the UE at the opposite end;

the third method comprises the following steps: receiving direct link communication channel data sent by opposite terminal UE to measure the beam quality;

in this way, the UE at the opposite end can send data of the direct link communication channel by using the beam failure measurement resource to measure the quality of the beam currently required to be measured;

the method is as follows: and receiving a special direct link beam measurement signal sent by the opposite terminal UE to carry out beam quality measurement.

In this way, the dedicated through link beam measurement signal is transmitted by using the beam failure measurement resource to measure the quality of the beam currently required to be measured.

The dedicated direct link beam measurement signal in this embodiment may be selectively configured to be a signal dedicated to direct link beam measurement, and may also be multiplexed into a signal having other functions according to requirements.

In this embodiment, the beam quality threshold included in the through link beam failure recovery configuration information includes, but is not limited to, at least one of the following:

a direct link synchronous reference signal receiving power threshold; a direct link discovery signal (including but not limited to a direct link discovery advertisement message and/or a direct link discovery response message) receive power threshold; a direct link communication channel receive power threshold; a receive power threshold of the dedicated through link beam measurement signal; a direct link synchronous reference signal receiving signal strength indication threshold; a direct link discovery signal received signal strength indication threshold; a direct link communication channel received signal strength indication threshold; the received signal strength of the dedicated through-link beam measurement signal indicates a threshold.

Of course, it should be understood that the thresholds may be set as other parameter thresholds according to the practical application scenario, besides the received power threshold and the signal strength indication threshold. The threshold in this embodiment may be used as a basis for selecting a beam with good quality, or may be used as a basis for determining that the beam quality is poor, and the specific use and the specific assignment of the threshold may be determined according to a specific application scenario.

In an example of the present example, after detecting that a currently used beam is failed, the triggering may be performed when it is further determined that the failure condition satisfies a preset failure condition. For example, in one example, after detecting that the currently used beam fails, the method may further include:

when the currently used wave beam is detected to be invalid, starting timing through a wave beam invalid detection timer, and adding 1 to a wave beam invalid example counting value;

before the beam failure detection timer is overtime, if the beam failure is detected again, resetting the beam failure detection timer for re-timing, and adding 1 to the count value of the beam failure example; on the contrary, if the beam failure detection timer is overtime, the beam failure is not detected any more, and the counting value of the beam failure example is set to be 0;

in the above process, if the current beam failure instance count value is greater than or equal to the maximum number of beam failure instances, it is determined that the through link beam failure recovery condition is triggered.

By the example mode, the accuracy and the stability of beam failure detection can be improved; it should be understood that the preset failure condition in the present embodiment is not limited to the above example, and for example, n (n may be an integer value equal to or greater than 2) times of beam failures may be continuously detected within a preset time period.

In this embodiment, the manner of sending the beam failure recovery processing message to the peer UE for beam recovery processing may include, but is not limited to, at least one of the following manners:

the first method is as follows: selecting a beam resource (which may be referred to as a target candidate beam resource) from the candidate beam resources, and sending a beam failure recovery request message to the opposite-end UE through the selected beam resource, where the beam failure recovery request message includes identification information of the local-end UE, and here is identification information of the source UE;

when receiving a beam failure recovery response message sent by the peer UE through the beam resource (i.e., the target candidate beam resource), the beam failure recovery is successful, where the beam failure recovery response message includes identification information of the peer UE, and here is identification information of the target UE; in this mode, after determining that the beam failure recovery is successful, the source UE may switch to the beam resource to perform direct link communication with the UE of the opposite end;

it should be understood that the identification information of the UE in this embodiment may be UE identification information (destination layer 2 ID), or pair identification information negotiated by the UE, or other identification information that may be capable of identifying the UE.

The second method comprises the following steps: selecting a beam resource (i.e. the target candidate beam resource) from the candidate beam resources, and sending direct link Control Information (SCI) to the peer UE through the selected beam resource, where the sent direct link Control Information includes but is not limited to at least one of the following:

identification information of the local UE (here, identification information of the source UE), identification information of the peer UE (here, identification information of the target UE), beam failure recovery indication (this embodiment may also be referred to as BFR indication for short), new beam direction, and no data transmission indication information;

in this embodiment, optionally, after receiving the direct link control information on the target candidate beam resource, the UE at the opposite end (i.e., the target UE) may switch to the target candidate beam resource according to at least one of the information included in the direct link control information, and optionally, may also send feedback information used for representing the received SCI or information for confirming beam failure recovery to the source UE; optionally, the source UE may also switch to the target candidate beam resource after receiving feedback information or beam failure recovery confirmation information used to characterize that the UE of the opposite end receives the SCI.

In addition to the above-mentioned exemplary manner, in this embodiment, the beam failure recovery may be performed by using the direct link discovery resource through a direct link discovery signal, for example:

the third method comprises the following steps: when determining that a mode a direct link discovery (i.e., model a sidelink discovery) mode is supported according to the supported direct link discovery mode indication information, sending a direct link discovery advertisement message (i.e., sidelink discovery notification message) in each beam direction, where the direct link discovery advertisement message includes a beam failure recovery indication to be distinguished from other Model a sidelink discovery messages, and optionally may further include identification information of the source UE; the beam failure recovery indication in this embodiment may include, but is not limited to, at least one of a beam recovery flag (i.e., beam recovery flag), a beam switch flag (i.e., beam switch), and a beam update flag (i.e., beam update flag);

and then, receiving PC5 signaling (optionally, the PC5 signaling may include identification information of the target UE) including the new beam direction sent by the peer UE (i.e., the target UE), or receiving PC5 signaling sent by the peer UE in at least one new beam direction (at this time, the PC5 signaling may not include an indication of the new beam direction), where the beam failure recovery is successful.

In this approach, the source UE may switch to the new beam direction for direct link communication with the peer UE after determining that the beam failure recovery was successful.

In this embodiment, when the PC5 signaling including the new beam direction sent by the peer UE (i.e., the target UE) is not received within a certain period of time, the direct link discovery advertisement message may be selectively retransmitted in each beam direction, and the maximum retransmission number may be set.

The method four comprises the following steps: when determining that a mode B direct link discovery (i.e., model B sidelink discovery) mode is supported according to the supported direct link discovery mode indication information, sending a direct link discovery request message in at least one beam direction, where the direct link discovery request message includes a beam failure recovery indication to be distinguished from other Model B sidelink discovery messages, and optionally may also include an identifier of the source UE; the beam failure recovery indication in this embodiment may include, but is not limited to, at least one of a beam recovery flag (i.e., beam recovery flag), a beam switch flag (i.e., beam switch), and a beam update flag (i.e., beam update flag);

and receiving a direct link discovery response message (which optionally may include identification information of the target UE) sent by the peer UE in one beam direction, wherein the beam failure recovery is successful.

In this manner, after determining that the beam failure recovery is successful, the source UE may switch to direct link communication with the peer UE in the beam direction.

In this embodiment, when the direct link discovery response message sent by the peer UE (i.e., the target UE) is not received within a certain time period, the direct link discovery request message may also be selectively retransmitted in each beam direction, and the maximum retransmission number may be set.

Optionally, for the first and second manners, the manner of selecting the beam resource from the candidate beam resources may include, but is not limited to:

the first method is as follows: selecting a beam resource with a beam quality higher than the beam quality threshold from candidate beam resources, for example, selecting a beam resource with a beam quality higher than the beam quality threshold (the specific setting of the threshold can be flexibly set according to an application scenario) from the beam failure recovery dedicated resource and/or the beam failure recovery contention resource pool;

the second method comprises the following steps: selecting a beam resource with the highest beam quality from the candidate beam resources is based on, for example, selecting a beam resource with the highest beam quality from a beam failure recovery dedicated resource and/or a beam failure recovery contention resource pool.

Optionally, when the beam failure recovery processing is executed in the first manner, the following three triggering manners of beam resource reselection may also be included, but are not limited to:

the first method is as follows: after sending a beam failure recovery request message to the opposite terminal UE through the selected beam resource, starting timing through a beam failure recovery request retransmission timer;

when the beam failure recovery request retransmission timer is overtime, if the beam failure recovery response message sent by the opposite-end UE is not received, retransmitting the beam failure recovery request message to the opposite-end UE through the selected beam resource, re-timing through the beam failure recovery request retransmission timer, and recording the retransmission times;

when the retransmission times are larger than the maximum retransmission times of the beam failure recovery request, reselecting a beam resource to send a beam failure recovery request message to opposite-end UE (namely the opposite-end UE);

the second method comprises the following steps: after sending a beam failure recovery request message to the opposite terminal UE through the selected beam resource, starting timing through a beam failure recovery timer;

and when the beam failure recovery timer is overtime, if the beam failure recovery response message sent by the opposite-end UE is not received, reselecting the beam resource to send the beam failure recovery request message to the opposite-end UE.

The third method comprises the following steps: after sending a beam failure recovery request message to the opposite terminal UE through the selected beam resource, starting timing through a beam failure recovery request retransmission timer and a beam failure recovery timer, optionally, the timing value of the beam failure recovery timer is greater than the timing value of the beam failure recovery request retransmission timer;

when the beam failure recovery request retransmission timer is overtime, if a beam failure recovery response message sent by the opposite-end UE is not received, retransmitting the beam failure recovery request message to the opposite-end UE through the selected beam resource, re-timing through the beam failure recovery request retransmission timer, and recording the retransmission times;

and when the retransmission times are more than the maximum retransmission times of the beam failure recovery request and/or the beam failure recovery timer is overtime and does not receive the beam failure recovery response message sent by the opposite terminal UE, reselecting the beam resource to send the beam failure recovery request message to the opposite terminal UE.

In an example of this embodiment, when the beam failure recovery fails, the direct link communication connection may also be selectively disconnected or released, for example, specific control manners include, but are not limited to, the following two manners:

the first method is as follows: when the times of reselecting the beam resource reach the maximum times of beam failure recovery or no beam resource meeting the conditions (for example, but not limited to the completion of the selection of the beam resource or the quality of the remaining beam resource does not meet the requirements) is selected, disconnecting or releasing the through link communication connection with the opposite-end UE;

the second method comprises the following steps: when the number of times of reselecting the beam resource reaches the maximum number of times of beam failure recovery or no beam resource meeting the condition is currently selected, and no data is received from the opposite-end UE within a current preset time period (the current preset time period may be counting from the time when the beam failure is detected for the first time, or counting is determined to be started when the number of times of reselecting the beam resource reaches the maximum number of times of beam failure recovery or no beam resource meeting the condition is currently selected, etc.), the direct link communication connection with the opposite-end UE is disconnected or released.

In an example of this embodiment, when performing the beam failure recovery processing in the fourth manner, at least one beam direction may be directly selected from the candidate beam resources to perform the sending of the direct link discovery request message and the receiving of the direct link discovery response message, and this processing manner has the advantages that discovery periods may not be equal, the efficiency of beam failure recovery may be further improved, and the continuity of the service may be further improved; for example, in an example, when the beam failure recovery processing is performed in the fourth manner, the transmitting the through link discovery request message in at least one beam direction includes:

selecting at least one beam direction from the beam failure recovery dedicated resource and/or the beam failure recovery contention resource pool according to the beam index;

and transmitting the through link discovery request message in the selected at least one wave speed direction.

For the target UE side, the direct link beam management method thereof is shown in fig. 3, and may include but is not limited to:

s301: and receiving a beam failure recovery processing message sent by the opposite-end UE (namely the source UE).

The method for the source UE to transmit the beam failure recovery processing message includes, but is not limited to, the four methods described above.

S302: and performing beam failure recovery processing according to the received beam failure recovery processing message.

For ease of understanding, the present embodiment will be described below by way of example of processing procedures corresponding to the above four modes.

The first method is as follows: receiving a beam failure recovery request message sent by a peer UE (i.e., the source UE) through a beam resource selected from the candidate beam resources (i.e., a target candidate beam resource), wherein the beam failure recovery request message includes identification information of the peer UE (i.e., identification information of the source UE);

sending a beam failure recovery response message on the beam resource (i.e. the target candidate beam resource), and switching to the beam resource to perform direct link communication with the opposite UE, where the beam failure recovery response message includes identification information of the local UE (i.e. identification information of the target UE);

the second method comprises the following steps: receiving through-link control information sent by the opposite-end UE through the beam resource selected from the candidate beam resources (i.e. the target candidate beam resource), wherein the through-link control information comprises at least one of the following: identification information of the local terminal UE (namely identification information of the target UE), identification information of the opposite terminal UE (namely identification information of the source UE), beam failure recovery indication, new beam direction and no data transmission indication information;

and switching to the new beam direction to carry out direct link communication with the opposite terminal UE.

The third method comprises the following steps: receiving a direct link discovery announcement message sent by a peer UE (i.e., the source UE) in each beam direction, where the direct link discovery announcement message includes a beam failure recovery indication, and the beam failure recovery indication in this embodiment may include but is not limited to at least one of a beam recovery identifier (i.e., a beam recovery identifier), a beam switch identifier (i.e., a beam switch), and a beam update identifier (i.e., a beam update identifier);

and sending PC5 signaling including the new beam direction to the peer UE in at least one beam direction, or sending PC5 signaling to the peer UE in at least one new beam direction (at this time, the PC5 signaling may optionally not include indication information of the new beam direction), and switching to the new beam direction to perform direct link communication with the peer UE.

The method is as follows: receiving a direct link discovery request message sent by a peer UE (namely, the source UE) in at least one beam direction (the beam direction may include a beam direction directly selected from the candidate beam resources), wherein the direct link discovery request message includes a beam failure recovery indication;

and in the beam direction of the received direct link discovery request message, selecting one beam direction to send a direct link discovery response message to the opposite terminal UE, and switching to the selected beam direction to carry out direct link communication with the opposite terminal UE.

Optionally, in this embodiment, before receiving the beam failure recovery processing message sent by the peer UE, the direct link beam failure recovery configuration information may also be sent to the peer UE.

Therefore, the through link beam failure recovery method provided by the embodiment can flexibly, quickly and reliably realize the recovery of beam failure when the beam fails, and ensures the continuity of service.

The second embodiment:

the through link beam management method provided in this embodiment may optionally perform the through link beam failure recovery method in the first embodiment, and may further perform beam reconfiguration processing when detecting a beam reconfiguration condition trigger.

Fig. 4 shows a schematic flow diagram of a process of performing beam reconfiguration at a source UE side initiating beam reconfiguration, and the process includes:

s401: and sending a reconfiguration message to the opposite UE in the current used beam direction (namely the source beam direction), wherein the reconfiguration message comprises the selected new beam direction and the identification information of the local UE (namely the source UE).

S402: when receiving a reconfiguration response message sent by the opposite-end UE in the current used beam direction or the new beam direction, switching to the new beam direction to carry out direct link communication with the opposite-end UE, wherein the reconfiguration response message comprises identification information of the opposite-end UE (namely target UE) and/or beam reconfiguration confirmation information.

In one example of this embodiment, the beam reconfiguration condition includes, but is not limited to, at least one of:

the first condition is as follows: the quality of the currently used beam is lower than a preset first beam quality threshold; at this time, the currently used beam may be able to basically maintain normal communication, but the communication effect is not optimal or does not meet the preset normal requirement;

and a second condition: there is currently a beam with a quality above the second beam quality threshold and the quality of this beam is higher than the currently used beam;

the second beam quality threshold is higher than the first beam quality threshold, and the setting of the specific threshold value can be flexibly set according to factors such as specific communication requirements and communication environments.

Of course, it should be understood that other reconfiguration conditions, such as other beams currently existing with a higher quality than the beam currently used, etc., may be flexibly set in addition to the conditions of the above example.

In an example of the present embodiment, the new beam direction selected in S401 may be, but is not limited to, the beam direction with the highest current beam quality, or one of the beam directions in the beam with the beam quality higher than the second beam quality threshold.

As shown in fig. 5, a schematic flow chart of a process of performing beam reconfiguration on a target UE side of an opposite end of a source UE initiating beam reconfiguration includes:

s501: receiving a reconfiguration message sent by a peer UE (i.e. a source UE) in a currently used beam direction, wherein the reconfiguration message comprises the selected new beam direction and identification information of the peer UE (i.e. the source UE).

S502: and sending a reconfiguration response message in the currently used beam direction or the new beam direction, and switching to the new beam direction to carry out direct link communication with the opposite-end UE (source UE), wherein the reconfiguration response message comprises identification information of the local-end UE (namely the target UE) and/or beam reconfiguration confirmation information.

Therefore, the through link beam management method provided by the embodiment can timely and reasonably reconfigure the beam when the beam is required to be reconfigured, thereby further ensuring the service quality and improving the system performance on the basis of ensuring the service continuity.

Example three:

for convenience of understanding, in the following description, the selection of the beam direction, the reconfiguration and the recovery of the beam failure during the Sidelink unicast communication are taken as examples in the present embodiment.

Example one: SIDELink unicast communication beam direction selection

For V2X sidelink unicast communication, resource configuration between unicast communication UEs may be configured based on beam directions of related beams, and sidelink unicast communication may be considered in the beam direction with better measured beam quality. When the UE performs unicast communication in a direction of selecting one beam, because the UE is always in a relatively moving state, and after a period of time, the beam may have poor quality, it is necessary to perform beam failure recovery to select a new beam, and switch to the new beam to continue to perform sidelink unicast communication, thereby ensuring the continuity of the service.

Before V2X SideLink unicast communication, the UE may perform SideLink Discovery and SideLink communication connection establishment (which may also be referred to as PC5 connection establishment) on an initiative SL BWP (initiative SideLink Band Width Part, generally configured by a base station or preset configuration), determine a SideLink unicast communication beam direction in the SideLink Discovery or SideLink communication connection establishment process, and negotiate the SL BWP used for SideLink unicast communication between the UE pair in the SideLink communication connection establishment process. The Sidelink discovery includes, but is not limited to, model A and Model B discovery modes.

In the Model a sidelink discovery mode, after UE1 in fig. 1 is assumed to acquire sidelink discovery resources on an initial SL BWP, send sidelink discovery notification (i.e., direct link discovery announcement) messages in various directions through a beam scanning beam surfing mode; after monitoring the sidelink discovery notification message of the UE1, the UE2 in fig. 1 acquires the sidelink communication resource on the initial SL BWP, and then selects one or more good-quality beam directions to send the PC5 connection establishment request message in the beam directions of the sidelink discovery notification received from the UE 1. The UE1 selects the beam direction with the best beam quality or selects one beam direction from a plurality of beam qualities in the beam directions of the PC5 connection establishment request messages of the UE2, and sends a PC5 connection establishment response message, wherein the beam direction is used as the sidelink unicast communication beam direction between the UE1 and the UE 2. This process, as shown in fig. 6, includes:

s601: UE1 obtains sidelink discovery resources;

s602: UE1 sends sidelink discovery notification message to UE 2;

s603: UE2 acquires sidelink communication resources;

s604: UE2 selects one or more beam directions with good beam quality to send a PC5 connection establishment request message to UE 1;

s605: the UE1 selects the beam direction with the best beam quality or selects one beam direction from a plurality of beam qualities in the beam directions for monitoring the PC5 connection establishment request message of the UE2, and sends a PC5 connection establishment response message.

In the Model B sidelink discovery mode, after UE1 in fig. 1 acquires sidelink discovery resources on an initial SL BWP, it sends a sidelink discovery request (i.e., direct link discovery request) message in each direction or in one or more selected beam directions through a beam surfing mode. The UE2 selects the beam direction with the best beam quality or selects one beam direction from a plurality of beam directions with better beam quality from the beam directions for monitoring the sidelink discovery request message of the UE1, and sends the sidelink discovery response message, wherein the beam direction is used as the sidelink unicast communication beam direction between the UEs. And the UE1 receives the sidelink discovery response message of the UE2, after acquiring the sidelink communication resource, the UE1 and the UE2 carry out the PC5 connection establishment process in the selected beam direction, and then carry out sidelink unicast communication. This process, as shown in fig. 7, includes:

s701: UE1 and UE2 obtain sidelink discovery resources;

s702: UE1 sends a sidelink discovery solicitation message to UE 2;

s703: the UE2 selects the beam direction with the best beam quality or selects one beam direction from a plurality of beam directions with better beam quality from the beam directions monitoring the sidelink discovery request message of the UE1, and sends a sidelink discovery response message;

s704: UE1 and UR2 acquire communication resources;

s705: and the UE1 and the UE2 carry out PC5 connection establishment in the selected beam direction.

Example two: beam beam reconfiguration

In this example, the measurement of the direct link beam, sidelink beam, may also include, but is not limited to, at least one of: a sidelink synchronization reference signal, a sidelink discovery signal, a sidelink communication channel quality measurement signal, a newly defined signal special for sidelink beam measurement; the corresponding beam threshold values may include, but are not limited to: the receiving power threshold of the sidelink synchronization reference signal, the receiving power threshold of the sidelink discovery signal, the receiving power threshold of the sidelink communication channel quality measurement signal, and the newly defined signal receiving power threshold special for the sidelink beam measurement.

And (3) performing beam direction reconfiguration on Sidelink unicast communication:

when the UE detects that the quality of the beam (namely the beam currently used) of the current sidelink unicast communication is reduced and is lower than a configured/preconfigured beam quality threshold 1 (namely a first beam quality threshold), and or detects that the quality of other beams is better and is higher than a configured/preconfigured beam quality threshold 2 (namely a second beam quality threshold), the UE selects the beam with the best beam quality or selects one beam from the beams higher than the beam quality threshold 2 as a new beam direction of the sidelink unicast communication. The UE sends a reconfiguration message (including but not limited to a sidelink reconfiguration message and a beam reconfiguration message) to the opposite UE in the original beam direction, wherein the reconfiguration message comprises a new beam direction indication and a source UE identity. After receiving the new beam direction indication, the peer UE sends a reconfiguration response message (including, but not limited to, sidelink reconfiguration response/completion message and beam reconfiguration response/completion message) in the original beam direction or in the new beam direction, where the reconfiguration response message includes a target UE identity and/or beam reconfiguration confirmation information. After receiving the response confirmation information of the opposite-end UE, the UE switches/updates to the new beam to perform sidelink unicast communication, thereby realizing the reconfiguration of the wave beam, further ensuring the service quality on the basis of ensuring the service continuity and improving the system performance.

Example three: sidelink beam failure recovery configuration

In order to recover as soon as possible after failure occurs in the currently used beam, and avoid affecting the continuity of sidelink unicast communication service, the UE may negotiate about the sidelink beam failure recovery related configuration information, which includes at least one of the following: whether to synchronize source UE indication information, supported direct link sidelink discovery mode indication information, a beam failure detection resource (i.e. beam failure detection resource), a beam failure detection timer (i.e. beam failure detection timer), a maximum beam failure instance number (i.e. maximum beam failure instance number), a candidate beam resource (i.e. candidate beam resource), a beam failure recovery timer (i.e. beam failure recovery timer), a beam failure recovery request retransmission timer (i.e. beam failure recovery request retransmission timer), a beam failure recovery request retransmission maximum number (i.e. beam failure recovery request retransmission maximum number), a beam failure recovery maximum number (i.e. beam failure recovery maximum number), and a beam quality threshold (i.e. beam quality threshold); wherein, the candidate beam resource may include but is not limited to at least one of the following:

the beam index (i.e., beam index), the direct link synchronization reference signal (i.e., sidelink synchronization reference signal), the direct link discovery signal (i.e., sidelink discovery signal), the direct link communication channel measurement signal, the dedicated direct link beam measurement signal (i.e., signal dedicated to sidelink beam detection), the direct link synchronization resource (i.e., sidelink synchronization resource), the direct link communication resource (i.e., sidelink communication resource for sidelink communication usage), the direct link discovery resource (i.e., sidelink discovery resource), the beam failure recovery dedicated resource (i.e., beam failure recovery dedicated resource), and the beam failure recovery contention resource pool (i.e., beam failure recovery contention resource pool).

If the synchronization source UE is determined according to the indication information of the synchronization source UE, the UE can periodically send a sidelink synchronization reference signal, and the opposite end UE can directly measure the quality of the signal detection beam; if not, the beam quality can be detected by other methods.

When the UE acquires the Sidelink beam failure recovery configuration information from the peer UE, the information may be sent by, but not limited to, one of the following manners: PC5 connection establishment (request) message, PC5 connection establishment response message, PC5 bearer configuration response message, PC5 reconfiguration message, sidelink beam failure recovery configuration message, other PC5 signaling message.

Optionally, after receiving the sildelink beam failure recovery configuration information from the peer UE, the UE may also send a corresponding response or acknowledgement message to the peer UE. For example, an interactive process of the Sidelink beam failure recovery configuration information is shown in fig. 8, and includes:

s801: UE2 sends a Sidelink beam failure recovery configuration to UE 1;

s802: UE1 sends a Sidelink beam failure recovery config ack to UE 2.

Example four: sidelink beam failure recovery trigger

When a physical layer of a UE (here, a source UE) detects a sidelink beam failure (a specific detection method of a beam failure may be the beam quality detection method described above, or may also be other methods, such as a packet loss rate, etc.), indicating a SL beam failure event to the MAC, starting or restarting a beam failure detection timer for timing, and adding 1 to the number of SL beam failure event counted by the MAC; when the beam failure detection timer is overtime, the number of SL beam failure instances counted by the MAC is set to be 0; and when the number of times of the SL bean failure instance indication reaches the maximum number of times of the bean failure instance configured in the sidelink bean failure recovery configuration information, triggering a sidelink bean failure recovery process.

Example five: execution of Sidelink beam failure recovery

The first method is as follows:

the method for sending the SL beam failure recovery request message to the opposite-end UE (namely the target UE) by the UE through selecting the beam resource from the candidate beam resources comprises the following steps: UE identification information (destination layer 2 ID), or pair of negotiated pair of UE identification information, or other identification information that can be used for the peer to identify the UE. And if the opposite-end UE receives the request message, replying a response message by using the corresponding beam resource. When the UE receives the SL beam failure recovery response/ack message of the peer UE, which includes the peer UE identification information (destination layer 2 ID), or the pair negotiated pair identification information of the UE, or other identification information that can be used by the UE to identify the peer UE, the SL beam failure recovery is successful. This procedure aims to let the UE pair know the new beam direction. The schematic flow diagram of the SL beam failure recovery is shown in fig. 9:

s901: the UE1 and the UE2 carry out direct link unicast communication;

s902: UE1 detects a Sildelink beam failure recovery trigger;

s903: the UE1 sends a SL beam failure recovery request message to the UE2 by adopting the mode;

s904: UE4 sends SL beam failure recovery response/ack message to UE2 by adopting the mode;

s905: UE1 and UE2 switch to the new beam direction for communication.

Optionally, in the first mode, the selection of beam from the candidate beam resource includes, but is not limited to, the following two modes: 1) Selecting a beam with candidate beam quality higher than a configured threshold value (namely a preset optimal quality threshold value) according to a beam quality threshold configured in the Sidelink beam failure recovery configuration information, wherein if a plurality of candidate beams meet the condition, the UE can realize selection of one candidate beam; 2) And if the corresponding beam quality threshold is not configured in the Sidelink beam failure recovery configuration information, selecting the beam with the highest beam quality.

Optionally, in the first mode, if the UE does not receive the response message of the peer UE within a certain time (beam failure recovery request retransmission timer) after sending the SL beam failure recovery request message, retransmitting the BFR request, and if the maximum retransmission number (beam failure recovery request retransmission maximum number) is reached, the BFR fails; the UE then performs beam reselection to try the BFR again.

Optionally, in the first manner, if the UE does not receive the response message of the peer UE within a certain time (the beam failure recovery timer) after sending the SL beam failure recovery request message, the beam failure recovery fails this time; when the beam failure recovery fails, the UE selects other candidate beams meeting the conditions to try again to perform the beam failure recovery.

Optionally, in the first manner, if the number of times of reselecting the beam reaches the maximum number of times of beam failure recovery, or no beam resource satisfying the condition is selectable, it may be determined that the beam failure recovery fails (optionally, when the number of times of reselecting the beam is increased and the UE does not receive data sent by the UE at the opposite end within a period of time), the PC5 connection between the UEs may be disconnected or released;

the second method comprises the following steps:

a sidelink beam Failure Recovery was performed by SCI. The UE selects a beam resource among the candidate beam resources to send SCI, which may include but is not limited to at least one of the following: UE identity, BFR indication, new beam direction, no indication of corresponding data transmission. After receiving the SCI, the peer UE (i.e., the target UE) performs sidelink communication with the UE in the new beam direction.

In this approach, if the UE ID is layer 2 UE ID 24bit, including the source target UE ID 48bit, exceeds the original SCI size, so in some instances it may be considered to negotiate a small size ID that the UE pair can recognize (and not conflict with other UE/UE pairs) at PC5 connection setup or beam Failure Recovery configuration, or to extend the SCI.

In this embodiment, when the UE triggers the sidelink beam Failure Recovery process, it may also trigger sidelink Recovery message sending, and perform sidelink beam Failure Recovery through sidelink Recovery, for example, see the following third and fourth modes.

The third method comprises the following steps:

for the Model a simple discovery manner, the source UE sends a sidelink discovery and notification message using a beam turning manner, in order to distinguish other discovery messages sent for the beam failure recovery, the discovery message may include a beam recovery/switch/update identifier, and if the peer UE (i.e. the target UE, receives a discovery message on an omnidirectional or some signal-good beam) receives a discovery message sent by the UE, the peer UE informs a new beam direction through PC5 signaling, such as beam/recovery signaling, in one or more beam directions with better beam quality. After receiving the PC5beam switch/recovery signaling, the source UE selects a beam direction reply response message, and then the beam failure recovery is successful. And the two UEs use the new beam direction to carry out sidelink unicast communication.

The method is as follows:

for the Model B simple discovery mode, the source UE selects to send a discovery solicitation message in one or more beam directions, and may include a beam discovery/switch/update flag in the discovery message and wait for a discovery response message in order to distinguish other discovery messages that are not sent for beam failure recovery. The peer UE (i.e. the target) selects the beam direction with the best beam quality or selects one beam direction from a plurality of beam directions with better beam quality from the beam directions for monitoring the sidelink discovery request message of the UE, and sends the sidelink discovery response message. If the source UE receives the discovery response message of the peer UE in one of the beam directions, the beam failure recovery succeeds, the source UE performs sidelink communication for switching to the beam direction, and the peer UE also performs sidelink communication for switching to the beam direction.

Optionally, in this embodiment, the source UE and the target UE may send Model B discovery/response messages using candidate beam resources configured in the sidelink beam failure recovery, so that it is not necessary to wait for a discovery cycle, if a response is received, the beam failure recovery succeeds, and the UE communication pair may be switched to a new beam direction for sidelink communication, which may improve the efficiency of beam failure recovery.

Example four:

the present embodiment further provides an authorization verification control scheme for a UE, as shown in fig. 10, which includes:

s1001: and the base station acquires the UE authorization information.

S1002: and the base station performs authorization verification on the UE.

In one example, the UE authorization information includes at least one of: direct link discovery authorization, direct link communication authorization, LTE direct link communication authorization, NR direct link unicast authorization, NR direct link broadcast/multicast authorization, the type of service supported by authorization, the role of service supported by authorization, the level of service automation supported by authorization.

In one example, the base station may perform authorization verification processing based on a resource request sent by the UE, and in this case, as shown in fig. 11, the method includes:

s1101: the base station obtains the UE authorization information, for example, the UE authorization information is obtained from an AMF (Access and Mobility management Function).

S1102: and the base station stores the acquired UE authorization information.

S1103: the base station receives a resource request sent by the UE.

S1104: and the base station performs authorization verification on the UE according to the stored UE authorization information.

In one example, the base station obtaining the UE authorization information may include, but is not limited to:

the base station obtains the UE authorization information from an AMF (Access and Mobility management Function) through the NG interface, for example, through but not limited to at least one of the following messages: a PDU (Protocol Data Unit, PDU) session resource establishment/modification request message, an initial context establishment request, a UE context modification request, a handover request;

the base station acquires UE authorization information from the adjacent base station through an Xn interface.

For example, in one example, after receiving a resource request sent by a UE, a base station may process the resource request according to authorization information in a UE context of the UE.

Optionally, the resource request sent by the UE includes a direct link communication resource request or a direct link discovery resource request; the base station processes the direct link communication/discovery resource request according to the authorization information in the UE context of the UE, and the processing comprises the following steps: and determining whether the UE can carry out direct link communication/discovery according to the authorization information, if so, configuring corresponding type resources for the UE.

Optionally, the direct link communication resource request includes a requested resource type;

the base station configuring the corresponding type resource for the UE comprises the following steps: and configuring resources for the UE according to the resource type of the direct link communication resource request.

Optionally, the resource type includes, but is not limited to, at least one of LTE V2X sidelink communication resources and NR V2X sidelink communication resources, NR V2X sidelink unicast communication resources, and NR V2X sidelink broadcast/multicast communication resources.

In another example, the resource request sent by the UE may optionally include a traffic type; the base station processes the resource request according to the authorization information in the UE context of the UE, and the processing comprises the following steps: and determining whether the UE supports the requested service according to the authorization information, if so, configuring communication resources for the UE.

Optionally, the resource request includes at least one of service role information and service automation level; the base station determines whether the UE supports the requested service according to the authorization information in the UE context of the UE, including but not limited to determining whether the UE is authorized to serve as its requested service role.

Optionally, the configuring, by the base station, the corresponding resource for the UE includes: and configuring corresponding communication resources for the UE according to the V2X service type and/or the service role in the service resource request.

Optionally, the service role information includes, but is not limited to: at least one of a Platoning leader UE, an automated UE, a remote driving UE, and an automation level.

Optionally, the V2X control function obtains UE authorization information; the V2X control function performs service authorization verification (service type, service role and service automation level) on the UE; the V2X control function may obtain UE authorization information from an HSS (Home Subscriber Server) or OAM (Operation Administration and Maintenance) configuration.

For example: for NR based V2X sidelink communication, if the base station has a relatively powerful function, for example, the gNB may schedule or configure LTE sidelink resources, when the UE requests a resource, the base station may verify, according to authorization information obtained in the context of the UE, whether the UE can perform LTE based V2X sidelink communication and/or NR based V2X sidelink communication, and then configure a corresponding type of resource for the UE; further, the UE may indicate which type (LTE V2X sidelink communication resources or NR V2X sidelink communication resources) of resources is requested when requesting resources.

For another example, UE capabilities and QoS required by different V2X service types are different (thereby affecting resource occupation, reservation, and scheduling policies), and when a UE needs to perform a certain V2X service, the base station verifies whether the UE authorizes to support the certain V2X service (e.g., a platform, an automatic driving, a remote driving, or a certain specific V2X service) according to the obtained authorization information in the context of the UE. Further, for the platoning, verifying whether the UE is authorized as a platoning leader; or, verifying whether the UE is authorized as an automatic UE, a remote driving UE and an authorized automation level of automation. Further, when requesting resources, the UE may indicate a V2X service type, a broadcasting leader UE, an automatic UE, a remote driving UE, an automatic level, and the like to be sent. In addition, service authorization by the V2X control function may be considered. The base station may obtain UE authorization information from the AMF or Xn interface message. The V2X control function may obtain UE authorization information from the HSS or OAM configuration.

Example five:

the present embodiment provides a direct link beam management apparatus, which can be applied to a UE as a source UE, and as shown in fig. 12, the apparatus includes:

a first information obtaining module 1201, configured to obtain straight-through link beam failure recovery configuration information;

the first processing module 1202 is configured to perform beam failure recovery processing according to the obtained through link beam failure recovery configuration information.

In one example, the first information obtaining module 1201 may be configured to obtain the through-link beam failure recovery configuration information by at least one of:

acquiring straight-through link beam failure recovery configuration information from a base station;

acquiring direct link beam failure recovery configuration information from UE of a communication opposite end;

acquiring straight-through link beam failure recovery configuration information from the pre-configuration information;

the specific acquisition process can be shown in the above embodiments.

In an example, the first processing module 1202 is configured to send a beam failure recovery processing message to the peer UE for beam recovery processing when detecting a through link beam failure recovery condition trigger according to the through link beam failure recovery configuration information.

Optionally, in one example, the through-link beam failure recovery configuration information includes at least one of:

whether to synchronize source UE indication information, supported direct link discovery mode indication information, beam failure detection resources, a beam failure detection timer, a maximum beam failure instance number, candidate beam resources, a beam failure recovery timer, a beam failure recovery request retransmission maximum number, a beam failure recovery maximum number, and a beam quality threshold.

In one example, the candidate beam resources include at least one of:

beam index, through link synchronization reference signal, through link discovery signal, through link communication channel measurement signal, dedicated through link beam measurement signal, through link synchronization resource, through link communication resource, through link discovery resource, beam failure recovery dedicated resource, beam failure recovery contention resource pool.

In one example, the first processing module 1202 detecting whether a through-link beam failure recovery condition is triggered comprises: it is detected whether the currently used beam is failed.

In an example, the first processing module may further be configured to detect the beam quality, where the specific detection manner includes, but is not limited to, the manner shown in the foregoing embodiments.

In one example, the first processing module 1202 is further configured to start timing by the beam failure detection timer when the beam failure is detected, and add 1 to the beam failure instance count value; and is used for before the beam failure detection timer is overtime, if detect the beam failure again, reset the beam failure detection timer and count the example count value of beam failure and add 1, on the contrary, set the example count value of beam failure as 0; the first processing module is further used for determining that the direct link beam failure recovery condition is triggered when the current beam failure instance count value is greater than or equal to the maximum beam failure instance number.

In one example, the first processing module 1202 is configured to send a beam failure recovery processing message to the peer UE for beam recovery processing by at least one of:

the first method is as follows: selecting beam resources from the candidate beam resources, and sending a beam failure recovery request message to the opposite-end UE through the selected beam resources, wherein the beam failure recovery request message comprises identification information of the local-end UE;

when receiving a beam failure recovery response message sent by the opposite-end UE through the beam resource, the beam failure recovery is successful, wherein the beam failure recovery response message comprises identification information of the opposite-end UE;

the second method comprises the following steps: selecting a beam resource from the candidate beam resources, and sending through link control information to the opposite terminal UE through the selected beam resource, where the through link control information includes at least one of the following:

identification information of local terminal UE, identification information of opposite terminal UE, beam failure recovery indication, new beam direction and no data transmission indication information;

the third method comprises the following steps: when determining that a direct link discovery mode of a support mode A is supported according to the indication information of the supported direct link discovery mode, sending a direct link discovery announcement message in each beam direction, wherein the direct link discovery announcement message comprises a beam failure recovery indication;

receiving PC5 signaling which is sent by opposite terminal UE and comprises a new wave beam direction, or receiving PC5 signaling which is sent by opposite terminal UE in at least one new wave beam direction, wherein the wave beam failure recovery is successful;

the method is as follows: when the direct link discovery mode of the mode B is determined to be supported according to the indication information of the supported direct link discovery mode, sending a direct link discovery request message in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and receiving a direct link discovery response message sent by the opposite-end UE in a beam direction, wherein the beam failure recovery is successful.

In one example, when the first processing module 1202 performs the beam failure recovery process by way four, the first processing module 1202 sending the direct link discovery request message in at least one beam direction includes:

selecting at least one beam direction from a beam failure recovery dedicated resource and/or a beam failure recovery contention resource pool;

and transmitting the through link discovery request message in the selected at least one wave speed direction.

Referring to fig. 12, the through link beam management apparatus in this embodiment further includes a first reconfiguration module 1203, configured to perform beam reconfiguration processing when the beam reconfiguration condition trigger is detected.

In one example, the first reconfiguration module 1203 is configured to send a reconfiguration message to the peer UE in the currently used beam direction, where the reconfiguration message includes the selected new beam direction and identification information of the peer UE;

and configured to switch to the new beam direction to perform direct link communication with the peer UE when receiving a reconfiguration response message sent by the peer UE in the current used beam direction or the new beam direction, where the reconfiguration response message includes identification information of the peer UE and/or beam reconfiguration confirmation information.

In one example, the first reconfiguration module 1203 beam reconfiguration condition includes at least one of:

the quality of the currently used beam is lower than a preset first beam quality threshold;

there is currently a beam with a quality above the second beam quality threshold and the quality of this beam is higher than the currently used beam;

the second beam quality threshold is higher than the first beam quality threshold.

In this embodiment, specific functions of the first information obtaining module 1201, the first processing module 1202, and the first reconfiguring module 1203 may be implemented by a processor or a controller in the UE, and implementation processes of the functions of the modules specifically refer to corresponding method portions in the foregoing embodiments, which are not described herein again.

The present embodiment further provides a direct link beam management apparatus, which can be applied to a UE as a target UE, and as shown in fig. 13, the apparatus includes:

a second information obtaining module 1301, configured to receive a beam failure recovery processing message sent by an opposite-end UE;

a second processing module 1302, configured to perform beam failure recovery processing according to the beam failure recovery processing message.

Referring to fig. 13, the direct link beam management apparatus may further include an information sending module 1304, configured to send direct link beam failure recovery configuration information to the peer UE before the second information obtaining module receives the beam failure recovery processing message sent by the peer UE.

In one example, the second processing module 1302 is configured to perform the beam failure recovery process by at least one of:

the first method is as follows: receiving a beam failure recovery request message sent by an opposite terminal UE through a beam resource selected from candidate beam resources, wherein the beam failure recovery request message comprises identification information of the opposite terminal UE;

sending a beam failure recovery response message on the beam resource, and switching to the beam resource to carry out direct link communication with the opposite terminal UE, wherein the beam failure recovery response message comprises identification information of the local terminal UE;

the second method comprises the following steps: receiving through link control information sent by an opposite-end UE through a beam resource selected from candidate beam resources, wherein the through link control information comprises at least one of the following information: identification information of local terminal UE, identification information of opposite terminal UE, beam failure recovery indication, new beam direction and no data transmission indication information;

switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the third method comprises the following steps: receiving a direct link discovery announcement message sent by opposite-end UE in each beam direction, wherein the direct link discovery announcement message comprises a beam failure recovery indication;

sending PC5 signaling comprising a new beam direction to the opposite terminal UE in at least one beam direction, or sending PC5 signaling to the opposite terminal UE in at least one new beam direction, and switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the method is as follows: receiving a direct link discovery request message sent by opposite terminal UE in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and in the beam direction of the received direct link discovery request message, selecting one beam direction to send a direct link discovery response message to the opposite terminal UE, and switching to the selected beam direction to carry out direct link communication with the opposite terminal UE.

Referring to fig. 13, the apparatus for direct link beam management further includes a second reconfiguration module 1303, configured to receive a reconfiguration message sent by the peer UE in a currently used beam direction, where the reconfiguration message includes a selected new beam direction and identification information of the peer UE; and configured to send a reconfiguration response message in the currently used beam direction or the new beam direction, and switch to the new beam direction to perform direct link communication with the peer UE, where the reconfiguration response message includes identification information and/or beam reconfiguration confirmation information of the peer UE.

In this embodiment, specific functions of the second information obtaining module 1301, the second processing module 1302, the second reconfiguration module 1303, and the information sending module 1304 may be implemented by a processor or a controller in the UE, and implementation processes of each function of each module are specifically referred to corresponding method portions in each embodiment, which are not described herein again.

Example six:

the present embodiment also provides a user equipment, which can be used as a source UE, as shown in fig. 14, and includes a first processor 1401, a first memory 1402, and a first communication bus 1403;

the first communication bus 1403 is used for realizing communication connection between the first processor 1401 and the first memory 1402;

the first processor 1401 is configured to execute one or more first programs stored in the first memory 1402 to implement the steps of the direct link beam management method on the source UE side as in the above embodiments.

The present embodiment also provides a user equipment, which can be used as a target UE, as shown in fig. 15, and includes a second processor 1501, a second memory 1502, and a second communication bus 1503;

the second communication bus 1503 is used for realizing communication connection between the second processor 1501 and the second memory 1502;

the second processor 1501 is configured to execute one or more second programs stored in the second memory 1502 to implement the steps of the direct link beam management method on the target UE side as shown in the above embodiments.

The present embodiments also provide a computer-readable storage medium including volatile or non-volatile, removable or non-removable media implemented in any method or technology for storage of information such as computer-readable instructions, data structures, computer program modules or other data. Computer-readable storage media include, but are not limited to, RAM (Random Access Memory), ROM (Read-Only Memory), EEPROM (Electrically Erasable Programmable Read-Only Memory), flash Memory or other Memory technology, CD-ROM (Compact disk Read-Only Memory), digital Versatile Disks (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other medium which can be used to store the desired information and which can be accessed by a computer.

In one example, the computer readable storage medium in this embodiment may be used to store one or more first programs, which may be executed by one or more processors, to implement the steps of the direct link beam management method on the source UE side as shown in the above embodiments.

In another example, the computer readable storage medium in this embodiment may be used to store one or more second programs, which may be executed by one or more processors, to implement the steps of the direct link beam management method on the target UE side as shown in the above embodiments.

The present embodiment also provides a first computer program (or called first computer software), which can be distributed on a computer readable medium and executed by a computing apparatus, to implement at least one step of the direct link beam management method at the source UE side as shown in the above embodiments; and in some cases at least one of the steps shown or described may be performed in an order different than that described in the embodiments above.

The present embodiment further provides a second computer program (or called second computer software), which can be distributed on a computer readable medium and executed by a computing apparatus, to implement at least one step of the direct link beam management method on the target UE side as shown in the above embodiments; and in some cases at least one of the steps shown or described may be performed in an order different than that described in the embodiments above.

The present embodiment also provides a first computer program product comprising a computer readable means on which the first computer program as shown above is stored. The computer readable means in this embodiment may include a computer readable storage medium as shown above.

The present embodiment also provides a second computer program product comprising a computer readable means on which the second computer program as shown above is stored. The computer readable means in this embodiment may comprise a computer readable storage medium as shown above.

It will be apparent to those skilled in the art that all or some of the steps of the methods, systems, functional modules/units in the devices disclosed above may be implemented as software (which may be implemented as computer program code executable by a computing device), firmware, hardware, and suitable combinations thereof. In a hardware implementation, the division between functional modules/units mentioned in the above description does not necessarily correspond to the division of physical components; for example, one physical component may have multiple functions, or one function or step may be performed by several physical components in cooperation. Some or all of the physical components may be implemented as software executed by a processor, such as a central processing unit, digital signal processor, or microprocessor, or as hardware, or as an integrated circuit, such as an application specific integrated circuit.

In addition, communication media typically embodies computer readable instructions, data structures, computer program modules or other data in a modulated data signal such as a carrier wave or other transport mechanism and includes any information delivery media as known to one of ordinary skill in the art. Thus, the present invention is not limited to any specific combination of hardware and software.

The foregoing is a more detailed description of embodiments of the present invention, and the present invention is not to be considered limited to such descriptions. For those skilled in the art to which the invention pertains, numerous simple deductions or substitutions may be made without departing from the spirit of the invention, which shall be deemed to belong to the scope of the invention.

Claims (31)

1. A through-link beam management method, comprising:

acquiring direct link beam failure recovery configuration information;

according to the acquired beam failure recovery configuration information of the straight-through link, beam failure recovery processing is carried out;

the performing of the beam failure recovery processing according to the acquired beam failure recovery configuration information of the through link includes:

according to the through link beam failure recovery configuration information, when the through link beam failure recovery condition is triggered, sending a beam failure recovery processing message to opposite-end UE for beam recovery processing;

the sending the beam failure recovery processing message to the peer UE for beam recovery processing includes at least one of the following manners:

the first method is as follows: selecting beam resources from the candidate beam resources, and sending a beam failure recovery request message to the opposite-end UE through the selected beam resources, wherein the beam failure recovery request message comprises identification information of the local-end UE;

when receiving a beam failure recovery response message sent by the opposite-end UE through the beam resource, the beam failure recovery is successful, wherein the beam failure recovery response message comprises identification information of the opposite-end UE;

the second method comprises the following steps: selecting a beam resource from the candidate beam resources, and sending through link control information to the opposite terminal UE through the selected beam resource, wherein the through link control information includes at least one of the following:

identification information of local terminal UE, identification information of opposite terminal UE, beam failure recovery indication, new beam direction and no data transmission indication information;

the third method comprises the following steps: when the direct link discovery mode supporting mode A is determined according to the indication information of the direct link discovery mode supported, direct link discovery announcement messages are sent in all beam directions, wherein the direct link discovery announcement messages comprise beam failure recovery indications;

receiving PC5 signaling which is sent by opposite terminal UE and comprises a new wave beam direction or PC5 signaling which is sent by opposite terminal UE in at least one new wave beam direction, wherein the wave beam failure recovery is successful;

the method is as follows: when determining that a mode B direct link discovery mode is supported according to the supported direct link discovery mode indication information, sending a direct link discovery request message in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and receiving a direct link discovery response message sent by the opposite-end UE in a beam direction, wherein the beam failure recovery is successful.

2. The through-link beam management method according to claim 1, wherein the through-link beam failure recovery configuration information is obtained by at least one of:

acquiring straight-through link beam failure recovery configuration information from a base station;

acquiring direct link beam failure recovery configuration information from User Equipment (UE) of a communication opposite end;

and acquiring the direct link beam failure recovery configuration information from the pre-configuration information.

3. The direct link beam management method according to claim 1, wherein acquiring the direct link beam failure recovery configuration information from the UE at the opposite communication end includes acquiring the direct link beam failure recovery configuration information from the UE through at least one of the following messages:

PC5 connection establishment message, PC5 connection establishment response message, PC5 bearer configuration response message, PC5 reconfiguration message, direct link beam failure recovery configuration message.

4. The through-link beam management method according to any of claims 1-3, wherein the through-link beam failure recovery configuration information comprises at least one of:

whether to synchronize source UE indication information, supported direct link discovery mode indication information, beam failure detection resources, a beam failure detection timer, a maximum beam failure instance number, candidate beam resources, a beam failure recovery timer, a beam failure recovery request retransmission maximum number, a beam failure recovery maximum number, and a beam quality threshold.

5. The through-link beam management method of claim 4 wherein the candidate beam resources comprise at least one of:

beam index, through link synchronization reference signal, through link discovery signal, through link communication channel measurement signal, dedicated through link beam measurement signal, through link synchronization resource, through link communication resource, through link discovery resource, beam failure recovery dedicated resource, beam failure recovery contention resource pool.

6. The through-link beam management method of claim 5, wherein the method comprises at least one of:

receiving a direct link discovery announcement message sent by opposite terminal UE, and measuring beam quality according to the direct link discovery announcement message;

sending a direct link discovery request message to opposite terminal UE, receiving a direct link discovery response message sent by the opposite terminal UE, and measuring the beam quality according to the direct link discovery response message;

when the opposite-end UE is determined to be the synchronous source UE according to the synchronization source UE indication information, receiving a direct link synchronization reference signal sent by the opposite-end UE to carry out beam quality measurement;

receiving direct link communication channel data sent by opposite terminal UE to measure the beam quality;

and receiving the special through link beam measurement signal sent by the opposite terminal UE to carry out beam quality measurement.

7. The through-link beam management method of claim 4 wherein the beam quality threshold comprises at least one of:

a direct link synchronization reference signal received power threshold, a direct link discovery signal received power threshold, a direct link communication channel received power threshold, a dedicated direct link beam measurement signal received power threshold, a direct link synchronization reference signal received signal strength indication threshold, a direct link discovery signal received signal strength indication threshold, a direct link communication channel received signal strength indication threshold, a dedicated direct link beam measurement signal received signal strength indication threshold.

8. The through-link beam management method of claim 1 wherein detecting whether a through-link beam failure recovery condition is triggered comprises:

when the beam failure is detected, starting timing by the beam failure detection timer, and adding 1 to the count value of the beam failure example;

before the beam failure detection timer is overtime, if the beam failure is detected again, resetting the beam failure detection timer for re-timing, and adding 1 to the count value of the beam failure instance; otherwise, setting the beam failure example counting value to be 0;

and if the current beam failure example counting value is more than or equal to the maximum beam failure example times, determining that the through link beam failure recovery condition is triggered.

9. The through-link beam management method of claim 1 wherein the selecting a beam resource from the candidate beam resources comprises:

selecting a beam resource with beam quality higher than a beam quality threshold value from the candidate beam resources;

or the like, or, alternatively,

a beam resource with the highest beam quality is selected from the candidate beam resources.

10. The through-link beam management method according to claim 1, wherein when performing beam failure recovery processing in the first mode, further comprising:

after sending a beam failure recovery request message to opposite terminal UE through the selected beam resource, starting timing through a beam failure recovery request retransmission timer;

when the beam failure recovery request retransmission timer is overtime, if a beam failure recovery response message sent by the opposite-end UE is not received, retransmitting the beam failure recovery request message to the opposite-end UE through the selected beam resource, re-timing through the beam failure recovery request retransmission timer, and recording the retransmission times;

when the retransmission times are larger than the maximum retransmission times of the beam failure recovery request, reselecting beam resources to send a beam failure recovery request message to the opposite-end UE;

or the like, or, alternatively,

after the beam failure recovery request message is sent to the opposite terminal UE through the selected beam resource, timing is started through the beam failure recovery timer;

when the beam failure recovery timer is overtime, if the beam failure recovery response message sent by the opposite terminal UE is not received, the beam resource is reselected to send a beam failure recovery request message to the opposite terminal UE;

or the like, or a combination thereof,

after sending a beam failure recovery request message to opposite terminal UE through the selected beam resource, starting timing through a beam failure recovery request retransmission timer and a beam failure recovery timer;

when the beam failure recovery request retransmission timer is overtime, if the beam failure recovery response message sent by the opposite-end UE is not received, retransmitting the beam failure recovery request message to the opposite-end UE through the selected beam resource, re-timing through the beam failure recovery request retransmission timer, and recording the retransmission times;

and when the retransmission times are larger than the maximum retransmission times of the beam failure recovery request and/or the beam failure recovery timer is overtime and does not receive the beam failure recovery response message sent by the opposite terminal UE, reselecting the beam resource to send the beam failure recovery request message to the opposite terminal UE.

11. The direct link beam management method according to claim 10, wherein when the number of times of reselecting beam resources reaches the maximum number of times of beam failure recovery, or there is no beam resource currently satisfying a condition for selection, the direct link communication connection with the peer UE is disconnected or released;

or the like, or, alternatively,

and when the times of reselecting the beam resources reach the maximum times of beam failure recovery or no beam resources meeting the conditions are currently selected and no data is received from the opposite-end UE in the current preset time period, disconnecting or releasing the direct link communication connection with the opposite-end UE.

12. The through-link beam management method according to claim 1, wherein when performing beam failure recovery processing in the manner four, the transmitting a through-link discovery request message in at least one beam direction includes:

selecting at least one beam direction from a beam failure recovery dedicated resource and/or a beam failure recovery contention resource pool;

transmitting a through link discovery request message in the selected at least one wave speed direction.

13. The through-link beam management method of any of claims 1-3, wherein the method further comprises:

and when the beam reconfiguration condition trigger is detected, carrying out beam reconfiguration processing.

14. The through-link beam management method of claim 13 wherein the performing beam reconfiguration processing comprises:

sending a reconfiguration message to opposite-end UE in the current used beam direction, wherein the reconfiguration message comprises the selected new beam direction and the identification information of the local-end UE;

and when a reconfiguration response message sent by the opposite-end UE in the current used beam direction or the new beam direction is received, switching to the new beam direction to carry out direct link communication with the opposite-end UE, wherein the reconfiguration response message comprises identification information and/or beam reconfiguration confirmation information of the opposite-end UE.

15. The through-link beam management method of claim 13 wherein the beam reconfiguration condition includes at least one of:

the quality of the currently used beam is lower than a preset first beam quality threshold;

there is currently a beam of quality above the second beam quality threshold and the beam of quality is of higher quality than the beam currently used.

16. The through-link beam management method of claim 15 wherein the new beam direction selected is one of a beam direction having a highest current beam quality or a beam direction having a beam quality above the second beam quality threshold.

17. A through link beam management method, comprising:

receiving a beam failure recovery processing message sent by opposite terminal UE;

performing beam failure recovery processing according to the beam failure recovery processing message;

the receiving a beam failure recovery processing message sent by the opposite-end UE and performing beam failure recovery processing according to the beam failure recovery processing message include at least one of the following ways:

the first method is as follows: receiving a beam failure recovery request message sent by an opposite terminal UE through a beam resource selected from candidate beam resources, wherein the beam failure recovery request message comprises identification information of the opposite terminal UE;

sending a beam failure recovery response message on the beam resource, and switching to the beam resource to carry out direct link communication with the opposite terminal UE, wherein the beam failure recovery response message comprises identification information of the local terminal UE;

the second method comprises the following steps: receiving through link control information sent by an opposite-end UE through a beam resource selected from candidate beam resources, wherein the through link control information comprises at least one of the following information: identification information of opposite terminal UE, local terminal UE identification information, beam failure recovery indication, new beam direction and no data transmission indication information;

switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the third method comprises the following steps: receiving a direct link discovery announcement message sent by opposite-end UE in each beam direction, wherein the direct link discovery announcement message comprises a beam failure recovery indication;

sending PC5 signaling comprising a new beam direction to the opposite terminal UE in at least one beam direction, or sending PC5 signaling to the opposite terminal UE in at least one new beam direction, and switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the method is as follows: receiving a direct link discovery request message sent by opposite terminal UE in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and in the beam direction of the received direct link discovery request message, selecting one beam direction to send a direct link discovery response message to the opposite terminal UE, and switching to the selected beam direction to carry out direct link communication with the opposite terminal UE.

18. The through-link beam management method of claim 17, wherein the method further comprises:

before receiving a beam failure recovery processing message sent by an opposite terminal UE, sending straight-through link beam failure recovery configuration information to the opposite terminal UE.

19. The through-link beam management method according to any of claims 17-18, wherein the method further comprises:

receiving a reconfiguration message sent by opposite-end UE in a currently used beam direction, wherein the reconfiguration message comprises a selected new beam direction and identification information of the opposite-end UE;

and sending a reconfiguration response message in the current used beam direction or the new beam direction, and switching to the new beam direction to perform direct link communication with the opposite-end UE, wherein the reconfiguration response message comprises identification information and/or beam reconfiguration confirmation information of the local-end UE.

20. A direct link beam management apparatus, comprising:

the first information acquisition module is used for acquiring the beam failure recovery configuration information of the straight-through link;

the first processing module is used for carrying out beam failure recovery processing according to the acquired beam failure recovery configuration information of the through link;

the first processing module is used for sending a beam failure recovery processing message to opposite-end UE for beam recovery processing when detecting that a straight-through link beam failure recovery condition is triggered according to the straight-through link beam failure recovery configuration information;

the first processing module is configured to send a beam failure recovery processing message to the peer UE for beam recovery processing in at least one of the following manners:

the first method is as follows: selecting beam resources from the candidate beam resources, and sending a beam failure recovery request message to the opposite-end UE through the selected beam resources, wherein the beam failure recovery request message comprises identification information of the local-end UE;

when receiving a beam failure recovery response message sent by the opposite-end UE through the beam resource, the beam failure recovery is successful, wherein the beam failure recovery response message comprises identification information of the opposite-end UE;

the second method comprises the following steps: selecting a beam resource from the candidate beam resources, and sending through link control information to the opposite terminal UE through the selected beam resource, where the through link control information includes at least one of the following:

identification information of local terminal UE, identification information of opposite terminal UE, beam failure recovery indication, new beam direction and no data transmission indication information;

the third method comprises the following steps: when the direct link discovery mode supporting mode A is determined according to the indication information of the direct link discovery mode supported, direct link discovery announcement messages are sent in all beam directions, wherein the direct link discovery announcement messages comprise beam failure recovery indications;

receiving PC5 signaling which is sent by opposite terminal UE and comprises a new wave beam direction, wherein the PC5 signaling is sent by the opposite terminal UE in at least one new wave beam direction, and the wave beam failure recovery is successful;

the method is as follows: when determining that a mode B direct link discovery mode is supported according to the supported direct link discovery mode indication information, sending a direct link discovery request message in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and receiving a direct link discovery response message sent by the opposite-end UE in a beam direction, wherein the beam failure recovery is successful.

21. The direct link beam management apparatus according to claim 20, wherein the first information obtaining module is configured to obtain the direct link beam failure recovery configuration information by at least one of:

acquiring straight-through link beam failure recovery configuration information from a base station;

acquiring direct link beam failure recovery configuration information from UE of a communication opposite end;

and acquiring the through link beam failure recovery configuration information from the pre-configuration information.

22. The through-link beam management apparatus according to claim 20 or 21, wherein the through-link beam failure recovery configuration information includes at least one of:

whether to synchronize source UE indication information, supported direct link discovery mode indication information, beam failure detection resources, a beam failure detection timer, a maximum beam failure instance number, candidate beam resources, a beam failure recovery timer, a beam failure recovery request retransmission maximum number, a beam failure recovery maximum number, and a beam quality threshold.

23. The through-link beam management apparatus of claim 22 wherein the candidate beam resources comprise at least one of:

beam index, through link synchronization reference signal, through link discovery signal, through link communication channel measurement signal, dedicated through link beam measurement signal, through link synchronization resource, through link communication resource, through link discovery resource, beam failure recovery dedicated resource, beam failure recovery contention resource pool.

24. The direct link beam management apparatus of claim 20 wherein the first processing module is configured to start timing by the beam failure detection timer and add 1 to a beam failure instance count value when the beam failure is detected; and is used for before the stated wave beam is out of order and detects the timer and time out before being overtime, if detect the stated wave beam out of order and fail the timer to reset and count again, and the stated wave beam is out of order and example the count value is increased by 1, on the contrary, set the stated wave beam into out of order example the count value to 0; the first processing module is further configured to determine that a direct link beam failure recovery condition is triggered when the current beam failure instance count value is greater than or equal to the maximum beam failure instance number.

25. The direct link beam management apparatus according to claim 20 or 21, further comprising a first reconfiguration module configured to perform a beam reconfiguration process when the beam reconfiguration condition trigger is detected.

26. A direct link beam management apparatus, comprising:

a second information acquisition module, configured to receive a beam failure recovery processing message sent by an opposite-end UE;

the second processing module is used for carrying out beam failure recovery processing according to the beam failure recovery processing message;

the second processing module is configured to perform beam failure recovery processing in at least one of the following manners:

the method I comprises the following steps: receiving a beam failure recovery request message sent by an opposite terminal UE through a beam resource selected from candidate beam resources, wherein the beam failure recovery request message comprises identification information of the opposite terminal UE;

sending a beam failure recovery response message on the beam resource, and switching to the beam resource to carry out direct link communication with the opposite terminal UE, wherein the beam failure recovery response message comprises identification information of the local terminal UE;

the second method comprises the following steps: receiving through link control information sent by an opposite-end UE through a beam resource selected from candidate beam resources, wherein the through link control information comprises at least one of the following information: identification information of opposite terminal UE, local terminal UE identification information, beam failure recovery indication, new beam direction and no data transmission indication information;

switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the third method comprises the following steps: receiving a direct link discovery announcement message sent by opposite-end UE in each beam direction, wherein the direct link discovery announcement message comprises a beam failure recovery indication;

sending PC5 signaling comprising a new beam direction to the opposite terminal UE in at least one beam direction, or sending PC5 signaling to the opposite terminal UE in at least one new beam direction, and switching to the new beam direction to carry out direct link communication with the opposite terminal UE;

the method is as follows: receiving a direct link discovery request message sent by opposite terminal UE in at least one beam direction, wherein the direct link discovery request message comprises a beam failure recovery indication;

and in the beam direction of the received direct link discovery request message, selecting one beam direction to send a direct link discovery response message to the opposite terminal UE, and switching to the selected beam direction to carry out direct link communication with the opposite terminal UE.

27. The direct link beam management apparatus according to claim 26, further comprising an information sending module, configured to send direct link beam failure recovery configuration information to a peer UE before the second information obtaining module receives a beam failure recovery processing message sent by the peer UE.

28. The through-link beam management apparatus according to any of claims 26-27, further comprising a second reconfiguration module for receiving a reconfiguration message sent by a peer UE in a currently used beam direction, the reconfiguration message including the selected new beam direction and identification information of the peer UE; and the terminal is configured to send a reconfiguration response message in the currently used beam direction or the new beam direction, and switch to the new beam direction to perform direct link communication with the peer UE, where the reconfiguration response message includes identification information of the peer UE and/or beam reconfiguration confirmation information.

29. A user device comprising a first processor, a first memory, and a first communication bus;

the first communication bus is used for realizing communication connection between the first processor and the first memory;

the first processor is configured to execute one or more first programs stored in the first memory to implement the steps of the through-link beam management method according to any one of claims 1-16.

30. A user device comprising a second processor, a second memory, and a second communication bus;

the second communication bus is used for realizing communication connection between the second processor and the second memory;

the second processor is configured to execute one or more second programs stored in the second memory to implement the steps of the through-link beam management method according to any of claims 17-19.

31. A computer readable storage medium, characterized in that the computer readable storage medium stores one or more first programs executable by one or more processors to implement the steps of the through-link beam management method according to any one of claims 1-16;

or the like, or a combination thereof,

the computer readable storage medium stores one or more second programs executable by one or more processors to implement the steps of the through-link beam management method of any of claims 17-19.

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