WO2016173078A1

WO2016173078A1 - Data transfer method and system, and ue having relay function

Info

Publication number: WO2016173078A1
Application number: PCT/CN2015/080411
Authority: WO
Inventors: 张晨璐; 张云飞; 郑倩
Original assignee: 宇龙计算机通信科技(深圳)有限公司
Priority date: 2015-04-30
Filing date: 2015-05-29
Publication date: 2016-11-03
Also published as: CN105657838A; CN105657838B

Abstract

Disclosed are a data transfer method and system, and a UE having a relay function. The method comprises: receiving a UE signaling packet from a UE; when the UE is not a UE bearing the method of the present invention, performing decapsulation processing on the UE signaling packet according to a first preset protocol suite; performing format encapsulation on the decapsulation result according to a second preset protocol suite; and finally sending the result of the format encapsulation to a mobile communication network node, wherein the first preset protocol suite or the second preset protocol suite comprises an RRC protocol. Accordingly, in the present invention, the RRC protocol is comprised in a protocol system on which a relay function is implemented, that is, the RRC protocol is comprised in a relay-side protocol system of a relay UE, thereby providing technical support for radio resource control; when the present invention is applied, a technical person can configure a required RRC function in the relay UE according to the RRC protocol covered by the relay UE, so as to properly reduce the time delay in the process of the radio resource control.

Description

Data transfer transmission method, system and UE with relay function

This application claims priority to Chinese Patent Application No. 201510218461.0, entitled "Data Transfer Transmission Method, System and UE with Relay Function", submitted to the Chinese Patent Office on April 30, 2015. The content is incorporated herein by reference.

Technical field

The present invention belongs to the field of mobile communications technologies, and in particular, to a data transfer method and system, and a UE (User Equipment) having a relay function.

Background technique

The relay UE means that the UE has both the UE side function and the relay side function, that is, the UE serves as a controlled end of the mobile communication network, and provides the user with a terminal function such as making a call, and also provides data as a component of the mobile communication network. Relay function to increase network coverage and capacity.

Currently, the relay-side protocol system of the relay UE does not have an RRC (Radio Resource Control) layer, and thus the existing relay UE cannot provide technical support for any radio resource control function. All the radio resource control functions are required to be handed over to the mobile communication base station eNB, and the eNB performs signaling interaction with the UE accessing the relay UE in the radio resource control process by relaying the relay of the UE. However, the relay UE accessing the eNB has a delay, which is not conducive to fast radio resource control. Therefore, it is urgent to provide a relay UE or a relay mode capable of providing technical support for radio resource control to avoid excessive time. The QoS (Quality of Service) is supported by the relay UE.

Summary of the invention

In view of this, an object of the present invention is to provide a data relay transmission method and system, and a UE with a relay function, aiming to provide a relay mode capable of providing technical support for a radio resource control function to reduce radio resource control. The delay in the process.

To this end, the present invention discloses the following technical solutions:

A data transfer method is applied to a first user equipment, and the method includes:

Receiving a UE signaling packet from the user equipment UE;

When the UE is a UE other than the first user equipment, decapsulating the UE signaling packet according to the first preset protocol group, to obtain a first destination signaling;

Performing format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset protocol group includes radio resource control RRC protocol;

Transmitting the first destination signaling packet to a mobile communication network node.

The above method, preferably, further includes:

When the UE is the first user equipment, the UE signaling packet received from the first user equipment is used as the first destination signaling.

The above method, preferably, the decapsulating the UE signaling packet by using the first preset protocol group to obtain the first destination signaling, including:

The UE signaling packet is decapsulated according to the physical layer PHY protocol, the medium access control layer MAC protocol, the radio link control layer RLC protocol, the packet data convergence protocol PDCP, and the radio resource control RRC protocol, to obtain the first destination signaling. .

In the above method, preferably, the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, and the first destination signaling group is configured according to the second preset protocol group. Format encapsulation processing, including:

According to a preset aggregation rule, the M first destination signalings are aggregated into P first intermediate signaling packets, where P is a natural number not less than 1, and P≤M;

Performing preset terminal micro base station relay format encapsulation for each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, where The protocol header includes S UE identifiers, where the S UE identifiers are the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Each of the second intermediate signaling packets is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.

In the above method, preferably, the number of the UE signaling packet and the first destination signaling is one, and the formatting and processing the first destination signaling according to the second preset protocol group includes:

Performing a preset relay format encapsulation on the first destination signaling to obtain a third intermediate signaling packet; the third intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, The UE Identifying the source UE identifier for the destination signaling;

The third intermediate signaling packet is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.

The UE signaling packet is decapsulated according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.

The M first destination signaling is aggregated into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer to obtain P fifth intermediate signaling packets; the fifth intermediate signaling packet includes a relay protocol header, The relay protocol header includes S UE identifiers, respectively, the source UE identifiers of the S destination signalings constituting the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M ;

Each of the fourth intermediate signaling packets is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.

Performing a preset relay format encapsulation on the first destination signaling at the RRC protocol layer to obtain a sixth intermediate signaling packet; the sixth intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, where the UE identifier is a source UE identifier of the destination signaling;

The sixth intermediate signaling packet is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.

In the above method, preferably, the aggregation rule is any one of the following rules:

Pre-set aggregation rules based on signaling sources; preset aggregation rules based on signaling types; preset aggregation rules based on logical channels/channel groups; one-to-one mapping rules in independent transmission.

Receiving a node signaling packet from a mobile communication network node;

Decapsulating the node signaling packet by using a third preset protocol group, and obtaining a second destination signaling and a destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes an RRC protocol ;

When the UE corresponding to the target UE identifier is a UE other than the first electronic device, the second destination signaling and the destination UE identifier are format-encapsulated based on the fourth preset protocol group, and the second purpose is obtained. Signaling packet

And sending the second destination signaling packet to the destination UE corresponding to the destination UE identifier.

The above method, preferably, further includes:

When the UE corresponding to the target UE identifier is the first electronic device, the second destination signaling is used as the second destination signaling packet to be sent.

In the above method, preferably, the node signaling packet includes K signaling and K target UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; Decapsulating the node signaling packet, and obtaining the second destination signaling and the destination UE identifier corresponding to the second destination signaling, including:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol;

Decapsulating the demodulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.

In the above method, preferably, the node data includes a signaling and a target UE identifier corresponding to the signaling, and then decapsulating the node signaling packet according to a third preset protocol group, to obtain a second purpose Signaling and the destination UE identifier corresponding to the second destination signaling, including:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling.

A data relay transmission device is applied to a first user equipment, and the device includes:

a first receiving module, configured to receive a UE signaling packet from the user equipment UE;

a first decapsulation module, configured to perform decapsulation processing on the UE signaling packet according to a first preset protocol group, to obtain a first destination message, when the UE is a UE other than the first user equipment make;

a first encapsulating module, configured to perform format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset The protocol group includes a radio resource control RRC protocol;

And a first sending module, configured to send the first destination signaling packet to a mobile communication network node.

The above device, preferably, further comprises:

The first processing module is configured to: when the UE is the first user equipment, use a UE signaling packet received by the first user equipment as the first destination signaling.

Preferably, the first decapsulation module comprises:

a first decapsulating unit, configured to sequentially solve the UE signaling packet according to a physical layer PHY protocol, a medium access control layer MAC protocol, a radio link control layer RLC protocol, a packet data convergence protocol PDCP, and a radio resource control RRC protocol Encapsulation, obtaining the first purpose signaling.

In the foregoing apparatus, preferably, the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the first encapsulating module includes:

a first aggregating unit, configured to aggregate the M first destination signaling into P first intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

a first encapsulating unit, configured to perform preset terminal micro base station relay format encapsulation on each of the first intermediate signaling packets, to obtain P second intermediate signaling packets; and the second intermediate signaling packet includes Following the protocol header, the relay protocol header includes S UE identifiers, where the S UE identifiers are the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is not less than 1. Natural number, and S ≤ M;

And a second encapsulating unit, configured to perform format encapsulation on each of the second intermediate signaling packets according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.

In the above apparatus, preferably, the number of the UE signaling packet and the first destination signaling is one, and the first encapsulating module includes:

a third encapsulating unit, configured to perform preset relay format encapsulation on the first destination signaling, to obtain a third intermediate signaling packet, where the third intermediate signaling packet includes a relay protocol header, and the relay The protocol header includes a UE identifier, and the UE identifier is a source UE identifier of the destination signaling;

The fourth encapsulating unit is configured to perform format encapsulation on the third intermediate signaling packet according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.

Preferably, the first decapsulation module comprises:

The second decapsulation unit is configured to decapsulate the UE signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.

a second aggregating unit, configured to aggregate the M first destination signaling into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤ M;

a fifth encapsulating unit, configured to perform preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer, to obtain P fifth intermediate signaling packets; where the fifth intermediate signaling packet includes a relay protocol header, the relay protocol header includes S UE identifiers, and the S UE identifiers are respectively source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is not less than 1 Natural number, and S ≤ M;

And a sixth encapsulating unit, configured to perform format encapsulation on each of the fourth intermediate signaling packets according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.

a seventh encapsulating unit, configured to perform a preset relay format encapsulation on the first destination signaling at the RRC protocol layer, to obtain a sixth intermediate signaling packet, where the sixth intermediate signaling packet includes a relay protocol header, The relay protocol header includes a UE identifier, and the UE identifier is a source UE identifier of the destination signaling;

The eighth encapsulating unit is configured to perform format encapsulation on the third intermediate signaling packet according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.

a second receiving module, configured to receive a node signaling packet from a mobile communication network node;

a second decapsulation module, configured to perform decapsulation processing on the node signaling packet by using a third preset protocol group, to obtain a second destination signaling, and a destination UE identifier corresponding to the second destination signaling, where the The three preset protocol groups include the RRC protocol;

a second encapsulating module, configured to: when the UE corresponding to the target UE identifier is another UE other than the first electronic device, perform the second destination signaling and the target UE identifier according to the fourth preset protocol group Format encapsulation to obtain a second destination signaling packet;

The second sending module is configured to send the second destination signaling packet to the destination UE corresponding to the destination UE identifier.

The above device, preferably, further comprises:

The second processing module is configured to use the second destination signaling as the second destination signaling packet to be sent when the UE corresponding to the target UE identifier is the first electronic device.

Preferably, the node signaling packet includes K signaling and K target UE identifiers corresponding to the K signaling, and K is a natural number greater than 1; then the second decapsulation module Includes:

a third decapsulation unit, configured to perform decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol;

And a splitting unit, configured to split the decapsulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.

Preferably, the node data includes a signaling and a destination UE identifier corresponding to the signaling, and the second decapsulation module includes:

a fourth decapsulation unit, configured to perform decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling .

A UE with a relay function, including a communication bus, a network interface, a memory, and a processor, wherein:

The communication bus is configured to implement connection communication between the network interface, the memory, and the processor;

The network interface is configured to receive a UE signaling packet from a user equipment UE;

The network interface is further configured to send the first destination signaling packet to the mobile communication network node;

The program stores a set of program codes, and the processor calls program code stored in the memory to perform the following operations:

Receiving a UE signaling packet from the user equipment UE;

Preferably, the processor further performs the following operations:

Preferably, the processor performs decapsulation processing on the UE signaling packet according to the first preset protocol group, to obtain the first destination signaling, which specifically includes:

Preferably, the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor performs the first destination signaling based on the second preset protocol group. Format encapsulation processing, including:

Performing preset relay format encapsulation for each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, and the relay protocol header The S UE identifiers are respectively the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Preferably, the number of the UE signaling packet and the first destination signaling is one, and the processor performs format encapsulation processing on the first destination signaling according to the second preset protocol group, specifically:

Performing a preset relay format encapsulation on the first destination signaling to obtain a third intermediate signaling packet; the third intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, The UE identifier is a source UE identifier of the destination signaling;

Preferably, the aggregation rule is any one of the following rules:

A UE with a relay function, comprising: a communication bus, a network interface, a memory, and a processor, wherein:

The network interface is configured to receive a node signaling packet from a mobile communication network node;

The network interface is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier;

Receiving a node signaling packet from a mobile communication network node;

When the UE corresponding to the target UE identifier is another UE other than the first electronic device, based on And the fourth preset protocol group performs format encapsulation on the second destination signaling and the destination UE identifier, to obtain a second destination signaling packet;

Preferably, the processor further performs the following operations:

Preferably, the node signaling packet includes K signaling and K destination UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; then the processor is based on a third preset protocol. The group performs decapsulation processing on the node signaling packet, and obtains the second destination signaling and the destination UE identifier corresponding to the second destination signaling, which specifically includes:

Preferably, the node data includes a signaling and a target UE identifier corresponding to the signaling, and the processor decapsulates the node signaling packet according to a third preset protocol group to obtain a second The target signaling and the destination UE identifier corresponding to the second destination signaling, specifically include:

A UE with a relay function, comprising: a communication bus, a first network interface, a second network interface, a memory, and a processor, wherein:

The communication bus is configured to implement connection communication between the first network interface, the second network interface, the memory, and the processor;

The first network interface is configured to receive a UE signaling packet from the user equipment UE;

The first network interface is further configured to send the first destination signaling packet to the mobile communication network node;

The second network interface is configured to receive a node signaling packet from a mobile communication network node;

The second network interface is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier;

Receiving a UE signaling packet from the user equipment UE;

Transmitting the first destination signaling packet to a mobile communication network node;

Receiving a node signaling packet from a mobile communication network node;

Preferably, the processor further performs the following operations:

Preferably, the aggregation rule is any one of the following rules:

Preferably, the processor further performs the following operations:

According to the above solution, the present invention receives a UE signaling packet from the UE; when the UE is not the first user equipment that carries the method of the present invention, the UE signaling packet is decapsulated based on the first preset protocol group, and Formatting the decapsulation result based on the second preset protocol group, and finally, transmitting the result of the format encapsulation to the mobile communication network node. The first preset protocol group or the second preset protocol group includes an RRC protocol. It can be seen that the RRC protocol is included in the protocol system for implementing the relay function, that is, the RRC protocol is incorporated into the relay side protocol system of the relay UE, which is a radio resource. The control provides technical support and improves the QoS support capability of the relay UE. When applying the present invention, the technician can configure the required RRC function in the relay UE based on the RRC protocol covered by the relay UE, so as to appropriately reduce the radio resource. The delay in the control process.

DRAWINGS

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below. Obviously, the drawings in the following description are only It is an embodiment of the present invention, and those skilled in the art can obtain other drawings according to the provided drawings without any creative work.

1 is a flow chart of a data transfer transmission method according to Embodiment 1 of the present invention;

2 is a protocol structure of a control plane protocol stack in a relay solution according to Embodiment 1 of the present invention;

3 is a schematic diagram of a UE relay principle according to Embodiment 1 of the present invention;

4 is a schematic diagram of a radio bearer of a relay function sublayer according to Embodiment 1 of the present invention;

FIG. 5 is a schematic diagram of an uplink signaling relay process according to Embodiment 1 of the present invention; FIG.

6 is another flowchart of a data transfer transmission method according to Embodiment 2 of the present invention;

7 is a schematic structural diagram of a data relay transmission apparatus according to Embodiment 3 of the present invention;

8 is another schematic structural diagram of a data relay transmission apparatus according to Embodiment 4 of the present invention;

9 is a schematic structural diagram of a UE with a relay function according to Embodiment 1 of the present invention;

FIG. 10 is another schematic structural diagram of a UE with a relay function according to Embodiment 2 of the present invention; FIG.

FIG. 11 is another schematic structural diagram of a UE with a relay function according to Embodiment 3 of the present invention.

detailed description

The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, but not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative efforts are within the scope of the present invention.

Embodiment 1

Embodiment 1 of the present invention discloses a data transfer transmission method, which is applied to a first user equipment, and refers to Figure 1, the method can include the following steps:

S101: Receive a UE signaling packet from the user equipment UE.

The source UE of the UE signaling packet may be another UE other than the first user equipment that carries the method of the present invention, that is, an access UE accessing the relay UE. In other embodiments of the present invention, the source UE of the UE signaling packet may also be a first user equipment that carries the method of the present invention, that is, a relay UE.

This application only describes the relaying of signaling data.

The existing protocol stack of the existing ordinary UE, that is, the protocol stack required to implement the terminal functions such as making a call and sending a short message, includes: a data plane protocol stack for providing technical support for receiving and transmitting user data, and Receive and send signaling data to provide technical support for the control plane protocol stack.

The control plane protocol stack includes a PHY (Physical Layer, Physical Layer) protocol, a MAC (Media Access Control) protocol, an RLC (Radio Link Control) protocol, and a PDCP (from the bottom layer to the upper layer). Packet Data Convergence Protocol, Packet Data Convergence Protocol, RRC (Radio Resource Control) protocol, and NAS (Non-access stratum, non-access stratum) protocol, the UE implements its corresponding according to various protocols in the above protocol stack. The features required for the layer.

In order to implement the relaying scheme, the UE has a data relay function capable of providing technical support for radio resource control on the basis of having a terminal function such as making a call and transmitting a short message, and referring to the relay UE protocol stack shown in FIG. Structure, in this embodiment, a virtual relay function sublayer is added on the RRC layer or the RRC layer of the original control plane protocol stack of the UE, that is, the relay function sublayer may be an independent protocol layer above the RRC layer. It can also be an increase in the functionality of the original RRC layer.

On the basis of this, as shown in FIG. 2, the PHY, the MAC, the RLC, the PDCP, the RRC, the relay function sub-layer, and the NAS layer protocol are used as the UE function-side protocol of the UE, and the UE receives and sends the base station data by using the UE role. The PHY, the MAC, the RLC, the PDCP, the RRC, and the relay function sub-layer protocol are used as the relay function-side protocol of the UE, and the UE is configured to receive and send data of the UE to the UE in the relay role and to access the UE. Providing technical support for the RRC control; wherein, in this embodiment, the relay function side and the UE function side independently have respective RLC, MAC, PHY, PDCP, and RRC layers. In other embodiments of the present invention, the relay function side And the UE function side can also combine the shared protocols of the UE function side and the relay function side by sharing one or more of the above layers to reduce redundancy.

The relay function side and the UE function side can realize the logical connection between the two function sides through the shared relay function sub-layer. Based on this, the UE can realize the relationship between the UE role and the relay role in the process of relaying data. Role conversion. For example, the UE receives the to-be-transferred signaling data from the base station in the UE role on the UE function side, and performs corresponding processing on the relay function sub-layer, and then the processed signaling data enters another functional side—relay On the function side, the UE is converted into a relay role by the UE role. Finally, the signaling data to be forwarded is forwarded by the relay function side of the UE in the relay role.

After the relay function sublayer is added on the RRC layer or the RRC layer of the original protocol stack of the UE, the UE has both the terminal function and the relay function, and becomes the relay UE, and the added relay function sublayer is in the RRC. On the layer or in the RRC layer, the RRC layer protocol is implemented in the relay function side protocol system of the relay UE, so that the relay UE can provide technical support for the radio resource control of the access UE, and the relay UE is improved. Support for QoS.

The technician can configure the required RRC function in the relay UE according to the RRC protocol covered in the relay UE protocol stack, for example, establish and maintain a UE-to-relay link, and perform UE-to-relay The link is managed, and the RRC function is shared by the base station, that is, a part of the RRC function is carried by the base station, and another part of the RRC function is carried by the relay UE, and all the RRC functions in the prior art are required to be carried by the base station. In the application of the present invention, the RRC control delay for accessing the UE can be appropriately reduced by causing the relay UE to assume part of the RRC function for the base station.

The functions of the relay function sublayer are defined below. Referring to FIG. 4, for example, relaying uplink data of the UE (the UE needs to send signaling to the base station), the A1/A2/A3 is the wireless signaling from the function side of the UE, that is, the signaling of the relay UE itself, such as Following the UE high-level NAS signaling or RRC signaling; B1/B2/B3 is the wireless signaling from the relay function side, that is, the signaling of accessing the UE.

In order to realize the distinction between the relay modality data (to be transferred to the UE from the access UE) and the UE modality data (the regular user signaling generated by the RRC/NAS layer of the relay UE), the relay function sublayer of the embodiment is provided. The following functions: Based on the different aggregation principles, the wireless signaling from the UE function side and the relay function side can be mapped in corresponding manners in the following manners:

First, based on signaling sources

Create a new RRC/NAS signaling, or borrow the original RRC/NAS signaling and extend the original signaling to carry all RRC/NAS signaling of the relay;

All RRC/NAS signaling originating from the same function side is aggregated and packaged in a new or extended RRC/NAS signaling for unified transmission.

The signaling packet formed by the aggregation and packing of the RRC/NAS signaling on the same function side includes the source of each signaling (such as a UE identifier) and the signaling type of each signaling (such as an RRC connection request, RRC Information such as the connection reconfiguration request) and the like is not limited to the above features.

Second, based on signaling type

The same type of RRC/NAS signaling originating from the UE function side and the relay function side is combined and packetized and transmitted. For example, the RRC Connection Reconfiguration (RRC Connection Reconfiguration) signaling of the UE function side and the relay function side is combined and packaged and transmitted.

Wherein, the source of each signaling (such as a UE identifier) needs to be given in the packetized packet obtained by the packet for the base station eNB to distinguish.

Third, based on logical channel / channel group

The signaling originating from the same logical channel/channel group is packaged and transmitted together. For example, the signaling of the same logical channel or channel group originating from the UE function side and the relay function side is packaged into one signaling packet for transmission. The source UE identifier of each signaling is also given in the final packetized signaling packet.

Fourth, independent transmission

The RRC/NAS signaling originating from the UE function side and the relay function side is not combined, that is, each RRC/NAS signaling is independently transmitted by the UE function side according to the conventional RRC processing.

The relay function sub-layer includes a relay protocol header in the signaling packet obtained by mapping the RRC/NAS signaling, so as to distinguish whether each signaling is from the UE function side or the relay function side of the relay UE, Setting an identifier bit in the relay protocol header; further, in order to distinguish RRC/NAS signaling originating from the relay function side but belonging to different access UEs, an identifier bit may be added to the relay protocol header for Differentiate between different UE sources.

The above definition of the relay function sub-layer and the function definition can be used as a pre-processing part of the method of the present invention.

On the basis of this, if the access UE needs to transmit signaling to the base station eNB through the relay UE, there is a signaling relay requirement. Referring to FIG. 5, the access UE sends RRC signaling or NAS signaling at the RRC layer or the NAS layer. The RRC signaling or the NAS signaling that is sent is sequentially encapsulated in a corresponding format by the conventional protocol stack (RRC, PDCP, RLC, MAC, PHY) of the access UE, and finally the radio of the UE is encapsulated into a corresponding format. Let the package be launched.

S102: Decapsulate the UE signaling packet according to the first preset protocol group, to obtain the first destination signaling, when the UE is a UE other than the first user equipment.

Taking the relay function sublayer as an independent protocol layer above the RRC layer as an example, when the relay side physical layer of the relay UE receives the signaling packet transmitted by the access UE, the signaling packet is forwarded and passed through The PHY, MAC, RLC, PDCP, and RRC protocol layers of the relay side protocol stack are solved by each protocol layer. After the encapsulation process, the first destination signaling is obtained, and the first destination signaling is delivered to the relay function sublayer processing.

It should be noted that, when the application is applied, when the relay function sub-layer is designed as the function of the RRC layer, the physical layer of the relay UE receives the UE data packet that accesses the UE, and then transmits the data packet upwards. It passes through the PHY, MAC, RLC, and PDCP protocol layers of the relay side protocol stack, performs decapsulation processing, and delivers it to the RRC layer, and performs required relay format encapsulation at the RRC layer.

In other embodiments of the present invention, when the relay UE needs to transmit signaling to the base station eNB, the RRC layer or the NAS layer of the relay UE sends RRC signaling or NAS signaling, and delivers it to the relay function sublayer for processing. .

S103: Perform format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet, where the first preset protocol group or the second preset protocol group includes a radio resource. Control the RRC protocol.

For example, if the relay function sublayer is an independent protocol layer, if the relay function sublayer of the relay UE receives M first destination signalings from multiple or one UE, the relay function sublayer is based on a preset aggregation rule, the M first destination signaling is aggregated into P first intermediate signaling packets; M is a natural number greater than 1, P is a natural number not less than 1, and P ≤ M;

And performing relay format encapsulation on each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, and the relay protocol header includes S a UE identifier, where the S UE identifiers are the source UE identifiers of the S first destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Then, the RRC layer, the PDCP layer, the RLC layer, the MAC layer, and the PHY layer of the UE function side respectively format and encapsulate the second intermediate data packet according to the corresponding protocol, to obtain P first destination signaling packets.

If the number of the first destination signaling received by the relay function sublayer of the relay UE is one, the relay function sublayer directly encapsulates the first destination signaling to obtain a third intermediate a signaling packet; the third intermediate signaling packet includes a relay protocol header, the relay protocol header includes a UE identifier, and the UE identifier is a source UE identifier of the first destination signaling; and thereafter, a UE functional side The RRC layer, the PDCP layer, the RLC layer, the MAC layer, and the PHY layer respectively format and encapsulate the third intermediate signaling packet according to the corresponding protocol to obtain a first destination signaling packet.

In other embodiments of the present invention, if the relay function sublayer is added as a function of the RRC protocol layer, the foregoing aggregation processing and the relay format encapsulation processing may be performed in the RRC protocol layer, and after performing the relay format encapsulation, Delivering the encapsulation result to the PDCP layer on the functional side of the UE, and then, in turn, by the function side of the UE The PDCP layer, the RLC layer, the MAC layer, and the PHY layer continue to perform format encapsulation thereon.

S104: Send the first destination signaling packet to a mobile communication network node.

Finally, the UE side physical layer of the relay UE may directly send the first destination signaling packet to the base station eNB, or transmit the first destination data packet to the base station by using a multi-hop relay. That is, the mobile communication network node may be a base station or a next hop relay based on the method of the present application.

The relay solution of the present application is applicable to a TSC (Terminal Small Cell) communication scenario and a D2D (Device-to-Device) direct connection communication scenario. According to the solution of the present application, the UE can provide the terminal function. At the same time, the data relay function is provided as a relay node in the above two communication scenarios.

According to the above solution, the present invention receives a UE signaling packet from the UE; when the UE is not the first user equipment that carries the method of the present invention, the UE signaling packet is decapsulated based on the first preset protocol group, and Formatting the decapsulation result based on the second preset protocol group, and finally, transmitting the result of the format encapsulation to the mobile communication network node. The first preset protocol group or the second preset protocol group includes an RRC protocol. It can be seen that the RRC protocol is included in the protocol system for implementing the relay function, that is, the RRC protocol is incorporated into the relay side protocol system of the relay UE, which provides technical support for the radio resource control and improves the QoS of the relay UE. Supporting capabilities, when applying the present invention, the technician can configure the required RRC function in the relay UE based on the RRC protocol covered by the relay UE to appropriately reduce the delay in the radio resource control process.

Embodiment 2

The second embodiment of the present invention discloses a data transfer method, which is applied to the first user equipment, and is different from the uplink signaling of the data transfer method in the first embodiment (that is, the UE transmits signaling to the base station). The method implements downlink signaling (base station transmits signaling to the UE) relay function. Referring to FIG. 6, the method may include the following steps:

S601: Receive a node signaling packet from a mobile communication network node.

In this embodiment, the mobile communication network node is a base station eNB, or a next hop relay based on the method of the present application.

S602: Perform decapsulation processing on the node signaling packet according to the third preset protocol group, to obtain a second destination signaling, and a destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes RRC agreement.

S603: When the UE corresponding to the target UE identifier is a UE other than the first electronic device, formatting the second destination signaling and the target UE identifier according to the fourth preset protocol group, and obtaining the first Two-purpose signaling package.

S604: Send the second destination signaling packet to the destination UE corresponding to the destination UE identifier.

The relaying of the downlink signaling by the relay UE is an inverse process for the uplink signaling relay, if the node signaling packet includes K signaling and K destination UE identifiers corresponding to the K signaling one-to-one , K is a natural number greater than 1, then:

After receiving the node signaling packet of the base station, the UE functional side physical layer of the relay UE decapsulates the node signaling packet through the PHY, MAC, RLC, PDCP, and RRC layers of the UE function side, and performs the relay function in the relay function. The demodulated node signaling packet is split into K signaling and K destination UE identifiers corresponding to the K signaling.

If the destination UE identifier of the split signaling corresponds to the relay UE, the relay function sublayer may directly transmit the signaling to the upper layer of the relay UE, that is, the RRC layer or the NAS layer; if the destination UE of the signaling When the identifier corresponds to the access UE, the relay function sublayer transmits the signaling to the RRC, PDCP, RLC, MAC, and PHY protocol layers of the relay function side protocol stack for format encapsulation, and then sends the signaling to the destination UE identifier. The corresponding accessing UE implements relaying of downlink signaling.

In other embodiments of the present invention, if the node signaling packet includes only one signaling and one destination UE identifier, the relay function sublayer of the relay UE does not need to send a node signaling packet to the RRC layer of the UE function side ( The de-encapsulated) performs signaling packet splitting.

Embodiment 3

The third embodiment of the present invention discloses a data relay transmission device, which is applied to a first user equipment. The device in this embodiment corresponds to the method in the first embodiment. Referring to FIG. 7, the device includes a first receiving module 100 and a first solution. The module 200, the first package module 300, and the first sending module 400 are packaged.

The first receiving module 100 is configured to receive a UE signaling packet from the user equipment UE.

The first decapsulation module 200 is configured to perform decapsulation processing on the UE signaling packet according to the first preset protocol group when the UE is a UE other than the first user equipment, to obtain a first purpose. Signaling.

The first encapsulating module 300 is configured to perform format encapsulation processing on the first destination signaling according to the second preset protocol group to obtain a first destination signaling packet; the first preset protocol group or the second pre- Set up an agreement The group includes the Radio Resource Control RRC protocol.

In this embodiment, the first decapsulation module includes a first decapsulation unit, configured to decapsulate the UE signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the first Destination signaling.

On the basis of the above, if the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the first encapsulating module 300 includes a first aggregation unit and a first encapsulation unit. And a second package unit.

a first encapsulating unit, configured to perform preset relay format encapsulation on each of the first intermediate signaling packets, to obtain P second intermediate signaling packets; and the second intermediate signaling packet includes a relay protocol header The relay protocol header includes S UE identifiers, where the S UE identifiers are the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S ≤ M;

If the number of the UE signaling packet and the first destination signaling is one, the first encapsulating module includes a third encapsulating unit and a fourth encapsulating unit.

The first sending module 400 is configured to send the first destination signaling packet to a mobile communication network node.

In another embodiment of the present invention, the first decapsulation module includes a second decapsulation unit, configured to decapsulate the UE signaling packet according to a PHY protocol, a MAC protocol, an RLC protocol, and a PDCP, to obtain a first Destination signaling.

Correspondingly, when the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the first encapsulating module includes a second aggregating unit, a fifth encapsulating unit, and a sixth encapsulation unit.

When the number of the UE signaling packet and the first destination signaling is one, the first encapsulating module includes a seventh encapsulating unit and an eighth encapsulating unit.

In another embodiment of the present invention, the apparatus further includes a first processing module, configured to: when the UE is the first user equipment, use a UE signaling packet received from the first user equipment as a first Destination signaling.

For the data relay transmission device disclosed in the third embodiment of the present invention, since it corresponds to the data transfer transmission method disclosed in the first embodiment, the description is relatively simple. For related similarities, refer to the data transfer transmission method in the first embodiment. Part of the description can be no longer detailed here.

Embodiment 4

The fourth embodiment of the present invention discloses a data relay transmission device, which is applied to the first user equipment, and is different from the uplink signaling relay function of the data relay transmission device in the third embodiment. Following the function, referring to FIG. 8, the apparatus includes a second receiving module 500, a second decapsulation module 600, a second encapsulating module 700, and a second transmitting module 800.

The second receiving module 500 is configured to receive a node signaling packet from a mobile communication network node.

a second decapsulation module 600, configured to perform decapsulation processing on the node signaling packet according to a third preset protocol group, to obtain a second destination signaling, and a destination UE identifier corresponding to the second destination signaling, where The third preset protocol group includes an RRC protocol.

If the node signaling packet includes K signaling and K destination UEs corresponding to the K signaling one-to-one The identifier, K is a natural number greater than 1; then the second decapsulation module comprises a third decapsulation unit and a split unit.

In another embodiment of the present invention, if the node data includes a signaling and a destination UE identifier corresponding to the signaling, the second decapsulation module includes a fourth decapsulation unit, which is configured according to the PHY protocol in sequence. The MAC protocol, the RLC protocol, the PDCP, and the RRC protocol perform decapsulation on the node signaling packet to obtain the signaling and the target UE identifier corresponding to the signaling.

The second encapsulating module 700 is configured to: when the UE corresponding to the target UE identifier is another UE other than the first electronic device, perform the second destination signaling and the target UE identifier according to the fourth preset protocol group. Perform format encapsulation to obtain a second destination signaling packet.

The second sending module 800 is configured to send the second destination signaling packet to the destination UE corresponding to the destination UE identifier.

In another embodiment of the present invention, the apparatus further includes: a second processing module, configured to: when the UE corresponding to the target UE identifier is the first electronic device, use the second destination signaling as a to-be-sent The second destination signaling packet.

For the data relay transmission device disclosed in the fourth embodiment of the present invention, since it corresponds to the data transfer transmission method disclosed in the second embodiment, the description is relatively simple. For related similarities, refer to the data transfer transmission method in the second embodiment. Part of the description can be no longer detailed here.

Embodiment 5

The fifth embodiment of the present invention discloses a UE with a relay function, including the data relay transmission device according to the third embodiment, and/or the data relay transmission device according to the fourth embodiment.

By integrating the functions of the data transfer device in the third embodiment and/or the fourth embodiment, the relay UE of the embodiment can provide the technology for the independent RRC control function of the relay UE while having the terminal function and the relay function. The RRC control delay is appropriately reduced, and the RRC control delay can be appropriately reduced by the relay UE to access the UE.

FIG. 9 is a block diagram showing the structure of a UE having a relay function according to an embodiment of the present invention. As shown in FIG. 9, the UE with the relay function in the embodiment of the present invention may include at least one network interface 903, at least one processor 901, such as a CPU, a memory 904, and at least one communication bus 902. The processor 901 may be combined with the figure. The data transfer device shown in 7.

The communication bus 902 is configured to implement connection communication between the network interface 903, the memory 904, and the processor 901.

The network interface 903 may include a standard wired interface or a wireless interface (such as a WI-FI interface). The network interface 903 is configured to receive a UE signaling packet from the user equipment UE. The network interface 903 is further configured to send the first destination signaling packet to the mobile communication network node.

The above memory 904 may be a high speed RAM memory or a non-volatile memory such as a magnetic disk memory. The memory 904 stores a set of program codes, and the processor 901 calls the program code stored in the memory 904 for performing the following operations:

Receiving a UE signaling packet from the user equipment UE;

Preferably, the processor 901 further performs the following operations:

Preferably, if the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor 901 performs signaling on the first destination based on the second preset protocol group. Format encapsulation Processing, specifically including:

Preferably, the number of the UE signaling packet and the first destination signaling is one, and the processor 901 performs format encapsulation processing on the first destination signaling according to the second preset protocol group, which specifically includes:

Preferably, if the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor 901 performs signaling on the first destination based on the second preset protocol group. Perform format encapsulation processing, including:

Each of the fourth intermediate letters is in turn according to PDCP, RLC protocol, MAC protocol, and PHY protocol The packet is formatted to obtain P first destination signaling packets.

Preferably, the aggregation rule is any one of the following rules:

Specifically, the terminal introduced in the embodiment of the present invention may be used to implement some or all of the processes in the method embodiment introduced by the present invention in conjunction with FIG.

FIG. 10 is a block diagram showing the structure of a UE having a relay function according to an embodiment of the present invention. As shown in FIG. 10, the UE with the relay function in the embodiment of the present invention may include at least one network interface 1003, at least one processor 1001, such as a CPU, a memory 1004, and at least one communication bus 1002. The processor 1001 may be combined with the figure. The data transfer device shown in 8.

The communication bus 1002 is configured to implement connection communication between the network interface 1003, the memory 1004, and the processor 1001.

The network interface 1003 may include a standard wired interface or a wireless interface (such as a WI-FI interface). The network interface 1003 is configured to receive a node signaling packet from a mobile communication network node. The network interface 1003 is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier.

The above memory 1004 may be a high speed RAM memory or a non-volatile memory such as a magnetic disk memory. The program 1001 stores a set of program codes, and the processor 1001 calls the program code stored in the memory 1004 for performing the following operations:

Receiving a node signaling packet from a mobile communication network node;

Decapsulating the signaling packet of the node according to a third preset protocol group, to obtain a second destination message And the destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes an RRC protocol;

Preferably, the processor 1001 further performs the following operations:

Preferably, the node signaling packet includes K signaling and K target UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; then the processor 1001 is based on the third preset The protocol group performs decapsulation processing on the node signaling packet, and obtains the second destination signaling and the destination UE identifier corresponding to the second destination signaling, which specifically includes:

Preferably, the node data includes a signaling and a destination UE identifier corresponding to the signaling, and the processor 1001 decapsulates the node signaling packet according to a third preset protocol group, to obtain a The destination UE identifier corresponding to the second destination signaling and the second destination signaling includes:

Specifically, the terminal introduced in the embodiment of the present invention may be used to implement some or all of the processes in the method embodiment introduced by the present invention in conjunction with FIG. 6.

FIG. 11 is a block diagram showing the structure of a UE having a relay function according to an embodiment of the present invention. As shown in FIG. 11, the UE with the relay function in the embodiment of the present invention may include at least one first network interface 1103, at least one second network interface 1104, at least one processor 1101, such as a CPU, a memory 1105, and at least one. The communication bus 1102, the processor 1101 can be combined with the data relay transmission device shown in FIGS. 7 and 8.

The communication bus 1102 is configured to implement connection communication between the first network interface 1103, the second network interface 1104, the memory 1105, and the processor 1101.

The first network interface 1103 may include a standard wired interface or a wireless interface (such as a WI-FI interface). The first network interface 1103 is configured to receive a UE signaling packet from the user equipment UE. The first network interface 1103 is further configured to send the first destination signaling packet to the mobile communication network node;

The second network interface 1104 described above may include a standard wired interface or a wireless interface (such as a WI-FI interface). The second network interface 1104 is configured to receive a node signaling packet from a mobile communication network node. The second network interface 1104 is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier.

The above memory 1105 may be a high speed RAM memory or a non-volatile memory such as a magnetic disk memory. The memory 1105 stores a set of program codes, and the processor 1101 calls the program code stored in the memory 1105 for performing the following operations:

Receiving a UE signaling packet from the user equipment UE;

Receiving a node signaling packet from a mobile communication network node;

Preferably, the processor 1101 also performs the following operations:

Preferably, the processor 1101 performs decapsulation processing on the UE signaling packet according to the first preset protocol group, to obtain the first destination signaling, which specifically includes:

Preferably, if the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor 1101 performs signaling on the first destination based on the second preset protocol group. Perform format encapsulation processing, including:

Preferably, the number of the UE signaling packets and the first destination signaling is one, and the processor 1101 performs a format encapsulation process on the first destination signaling according to the second preset protocol group, which specifically includes:

Preferably, the number of the UE signaling packet and the first destination signaling is M, and M is greater than 1. The processor 1101 performs format encapsulation processing on the first destination signaling according to the second preset protocol group, and specifically includes:

Preferably, the aggregation rule is any one of the following rules:

Preferably, the processor 1101 also performs the following operations:

Preferably, the node signaling packet includes K signaling and K target UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; then the processor 1101 is based on a third preset. The protocol group performs decapsulation processing on the node signaling packet, and obtains the second destination signaling and the destination UE identifier corresponding to the second destination signaling, which specifically includes:

Splitting the decapsulated node signaling packet into K signaling and K corresponding to the K signaling one-to-one Target UE ID.

Preferably, the node data includes a signaling and a target UE identifier corresponding to the signaling, and the processor 1101 performs decapsulation processing on the node signaling packet according to a third preset protocol group, to obtain a The destination UE identifier corresponding to the second destination signaling and the second destination signaling includes:

Specifically, the terminal introduced in the embodiment of the present invention may be used to implement some or all of the processes in the method embodiments introduced in conjunction with FIG. 1 and FIG.

It should be noted that each embodiment in the specification is described in a progressive manner, and each embodiment focuses on differences from other embodiments, and the same similar parts between the embodiments are referred to each other. can.

For the convenience of description, the above system is described as being divided into various modules or units by function. Of course, the functions of each unit may be implemented in the same software or software and/or hardware when implementing the present application.

It will be apparent to those skilled in the art from the above description of the embodiments that the present application can be implemented by means of software plus a necessary general hardware platform. Based on such understanding, the technical solution of the present application may be embodied in the form of a software product in essence or in the form of a software product, which may be stored in a storage medium such as a ROM/RAM or a disk. , an optical disk, etc., includes instructions for causing a computer device (which may be a personal computer, server, or network device, etc.) to perform the methods described in various embodiments of the present application or portions of the embodiments.

Finally, it should also be noted that in this context, relational terms such as first, second, third, fourth, etc. are only used to distinguish one entity or operation from another entity or operation, and not Any such actual relationship or order between these entities or operations must be required or implied. Furthermore, the term "comprises" or "comprises" or "comprises" or any other variations thereof is intended to encompass a non-exclusive inclusion, such that a process, method, article, or device that comprises a plurality of elements includes not only those elements but also Other elements, or elements that are inherent to such a process, method, item, or device. An element that is defined by the phrase "comprising a ..." does not exclude the presence of additional equivalent elements in the process, method, item, or device that comprises the element.

The above description is only a preferred embodiment of the present invention, and it should be noted that it is common to the art. The skilled person will be able to make several modifications and refinements without departing from the principles of the invention, and such modifications and refinements are also considered to be within the scope of the invention.

Claims

A data transfer method is applied to a first user equipment, and the method includes:

Receiving a UE signaling packet from the user equipment UE;

When the UE is a UE other than the first user equipment, decapsulating the UE signaling packet according to the first preset protocol group, to obtain a first destination signaling;

Performing format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset protocol group includes radio resource control RRC protocol;

Transmitting the first destination signaling packet to a mobile communication network node.
The method of claim 1 further comprising:

When the UE is the first user equipment, the UE signaling packet received from the first user equipment is used as the first destination signaling.
The method according to claim 2, wherein the decapsulating the UE signaling packet by using the first preset protocol group to obtain the first destination signaling includes:

The UE signaling packet is decapsulated according to the physical layer PHY protocol, the medium access control layer MAC protocol, the radio link control layer RLC protocol, the packet data convergence protocol PDCP, and the radio resource control RRC protocol, to obtain the first destination signaling. .
The method according to claim 3, wherein the number of the UE signaling packets and the first destination signaling is M, and M is a natural number greater than 1, the second preset protocol group pair The first destination signaling performs format encapsulation processing, including:

According to a preset aggregation rule, the M first destination signalings are aggregated into P first intermediate signaling packets, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation for each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, and the relay protocol header The S UE identifiers are respectively the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Each of the second intermediate signaling packets is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The method according to claim 3, wherein the number of the UE signaling packets and the first destination signaling is one, and the first destination signaling is performed based on the second preset protocol group. Format encapsulation processing, including:

Performing a preset relay format encapsulation on the first destination signaling to obtain a third intermediate signaling packet; the third intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, The UE identifier is a source UE identifier of the destination signaling;

The third intermediate signaling packet is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The method according to claim 2, wherein the decapsulating the UE signaling packet by using the first preset protocol group to obtain the first destination signaling includes:

The UE signaling packet is decapsulated according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.
The method according to claim 6, wherein the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the second preset protocol group pair The first destination signaling performs format encapsulation processing, including:

The M first destination signaling is aggregated into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer to obtain P fifth intermediate signaling packets; the fifth intermediate signaling packet includes a relay protocol header, The relay protocol header includes S UE identifiers, respectively, the source UE identifiers of the S destination signalings constituting the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M ;

Each of the fourth intermediate signaling packets is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The method according to claim 6, wherein the number of the UE signaling packets and the first destination signaling is one, and the first destination signaling is performed based on the second preset protocol group. Format encapsulation processing, including:

Performing a preset relay format encapsulation on the first destination signaling at the RRC protocol layer to obtain a sixth intermediate signaling packet; the sixth intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, where the UE identifier is a source UE identifier of the destination signaling;

And the sixth intermediate signaling packet is sequentially according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol. Perform format encapsulation to obtain the first destination signaling packet.
The method according to claim 4 or 7, wherein the aggregation rule is any one of the following rules:

Pre-set aggregation rules based on signaling sources; preset aggregation rules based on signaling types; preset aggregation rules based on logical channels/channel groups; one-to-one mapping rules in independent transmission.
A data transfer method is applied to a first user equipment, and the method includes:

Receiving a node signaling packet from a mobile communication network node;

Decapsulating the node signaling packet by using a third preset protocol group, and obtaining a second destination signaling and a destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes an RRC protocol ;

When the UE corresponding to the target UE identifier is a UE other than the first electronic device, the second destination signaling and the destination UE identifier are format-encapsulated based on the fourth preset protocol group, and the second purpose is obtained. Signaling packet

And sending the second destination signaling packet to the destination UE corresponding to the destination UE identifier.
The method of claim 10, further comprising:

When the UE corresponding to the target UE identifier is the first electronic device, the second destination signaling is used as the second destination signaling packet to be sent.
The method according to claim 11, wherein the node signaling packet comprises K signaling and K destination UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; Decapsulating the node signaling packet by using the third preset protocol group, and obtaining the second destination signaling and the destination UE identifier corresponding to the second destination signaling, including:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol;

Decapsulating the demodulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.
The method according to claim 12, wherein the node data comprises a signaling and a destination UE identifier corresponding to the signaling, and the node signaling packet is solved based on a third preset protocol group. The encapsulation process is performed to obtain the destination UE identifier corresponding to the second destination signaling and the second destination signaling, including:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling.
A data relay transmission device is characterized in that it is applied to a first user equipment, and the device includes:

a first receiving module, configured to receive a UE signaling packet from the user equipment UE;

a first decapsulation module, configured to perform decapsulation processing on the UE signaling packet according to a first preset protocol group, to obtain a first destination message, when the UE is a UE other than the first user equipment make;

a first encapsulating module, configured to perform format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset The protocol group includes a radio resource control RRC protocol;

And a first sending module, configured to send the first destination signaling packet to a mobile communication network node.
The device according to claim 14, further comprising:

The first processing module is configured to: when the UE is the first user equipment, use a UE signaling packet received by the first user equipment as the first destination signaling.
The device according to claim 15, wherein the first decapsulation module comprises:

a first decapsulating unit, configured to sequentially solve the UE signaling packet according to a physical layer PHY protocol, a medium access control layer MAC protocol, a radio link control layer RLC protocol, a packet data convergence protocol PDCP, and a radio resource control RRC protocol Encapsulation, obtaining the first purpose signaling.
The apparatus according to claim 16, wherein the number of the first signaling module of the UE and the number of the first destination signaling is M, and the M is a natural number greater than 1.

a first aggregating unit, configured to aggregate the M first destination signaling into P first intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

a first encapsulating unit, configured to perform preset relay format encapsulation on each of the first intermediate signaling packets, to obtain P second intermediate signaling packets; and the second intermediate signaling packet includes a relay protocol header The relay protocol header includes S UE identifiers, where the S UE identifiers are the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S ≤ M;

And a second encapsulating unit, configured to perform format encapsulation on each of the second intermediate signaling packets according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The device according to claim 16, wherein the number of the UE signaling packets and the first destination signaling is one, and the first encapsulating module comprises:

a third encapsulating unit, configured to perform preset relay format encapsulation on the first destination signaling, to obtain a third intermediate signaling packet, where the third intermediate signaling packet includes a relay protocol header, and the relay The protocol header includes a UE identifier, and the UE identifier is a source UE identifier of the destination signaling;

The fourth encapsulating unit is configured to perform format encapsulation on the third intermediate signaling packet according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The device according to claim 15, wherein the first decapsulation module comprises:

The second decapsulation unit is configured to decapsulate the UE signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.
The apparatus according to claim 19, wherein the number of the first signaling module of the UE and the number of the first destination signaling is M, and the M is a natural number greater than 1.

a second aggregating unit, configured to aggregate the M first destination signaling into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤ M;

a fifth encapsulating unit, configured to perform preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer, to obtain P fifth intermediate signaling packets; where the fifth intermediate signaling packet includes a relay protocol header, the relay protocol header includes S UE identifiers, and the S UE identifiers are respectively source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is not less than 1 Natural number, and S ≤ M;

And a sixth encapsulating unit, configured to perform format encapsulation on each of the fourth intermediate signaling packets according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The device according to claim 19, wherein the number of the UE signaling packets and the first destination signaling is one, and the first encapsulating module comprises:

a seventh encapsulating unit, configured to perform a preset relay format encapsulation on the first destination signaling at the RRC protocol layer, to obtain a sixth intermediate signaling packet, where the sixth intermediate signaling packet includes a relay protocol header, The relay protocol header includes a UE identifier, and the UE identifier is a source UE identifier of the destination signaling;

The eighth encapsulating unit is configured to perform format encapsulation on the third intermediate signaling packet according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
A data relay transmission device is characterized in that it is applied to a first user equipment, and the device includes:

a second receiving module, configured to receive a node signaling packet from a mobile communication network node;

a second decapsulation module, configured to perform decapsulation processing on the node signaling packet by using a third preset protocol group, to obtain a second destination signaling, and a destination UE identifier corresponding to the second destination signaling, where the three The preset protocol group includes the RRC protocol;

a second encapsulating module, configured to: when the UE corresponding to the target UE identifier is another UE other than the first electronic device, perform the second destination signaling and the target UE identifier according to the fourth preset protocol group Format encapsulation to obtain a second destination signaling packet;

The second sending module is configured to send the second destination signaling packet to the destination UE corresponding to the destination UE identifier.
The device according to claim 22, further comprising:

The second processing module is configured to use the second destination signaling as the second destination signaling packet to be sent when the UE corresponding to the target UE identifier is the first electronic device.
The apparatus according to claim 23, wherein the node signaling packet comprises K signaling and K destination UE identifiers corresponding to the K signalings, and K is a natural number greater than 1; The second decapsulation module includes:

a third decapsulation unit, configured to perform decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol;

And a splitting unit, configured to split the decapsulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.
The device according to claim 23, wherein the node data comprises a signaling and a destination UE identifier corresponding to the signaling, and the second decapsulation module comprises:

a fourth decapsulation unit, configured to perform decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling .
A UE with a relay function, comprising: a communication bus, a network interface, a memory, and a processor, wherein:

The communication bus is configured to implement connection communication between the network interface, the memory, and the processor;

The network interface is configured to receive a UE signaling packet from a user equipment UE;

The network interface is further configured to send the first destination signaling packet to the mobile communication network node;

The program stores a set of program codes, and the processor calls program code stored in the memory to perform the following operations:

Receiving a UE signaling packet from the user equipment UE;

When the UE is a UE other than the first user equipment, decapsulating the UE signaling packet according to the first preset protocol group, to obtain a first destination signaling;

Performing format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset protocol group includes radio resource control RRC protocol;

Transmitting the first destination signaling packet to a mobile communication network node.
The UE with relay function according to claim 26, wherein the processor further performs the following operations:

When the UE is the first user equipment, the UE signaling packet received from the first user equipment is used as the first destination signaling.
The UE with the relay function according to claim 27, wherein the processor performs decapsulation processing on the UE signaling packet based on the first preset protocol group, to obtain the first destination signaling, which specifically includes :

The UE signaling packet is decapsulated according to the physical layer PHY protocol, the medium access control layer MAC protocol, the radio link control layer RLC protocol, the packet data convergence protocol PDCP, and the radio resource control RRC protocol, to obtain the first destination signaling. .
The UE with the relay function according to claim 28, wherein the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor is based on The second preset protocol group performs format encapsulation processing on the first destination signaling, and specifically includes:

According to a preset aggregation rule, the M first destination signalings are aggregated into P first intermediate signaling packets, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation for each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, and the relay protocol header The S UE identifiers are respectively the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Each of the second intermediate signaling packets is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The UE with the relay function according to claim 28, wherein the number of the UE signaling packet and the first destination signaling is one, and the processor is based on the second preset protocol group Description The first destination signaling performs format encapsulation processing, and specifically includes:

Performing a preset relay format encapsulation on the first destination signaling to obtain a third intermediate signaling packet; the third intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, The UE identifier is a source UE identifier of the destination signaling;

The third intermediate signaling packet is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The UE with the relay function according to claim 27, wherein the processor performs decapsulation processing on the UE signaling packet based on the first preset protocol group, to obtain the first destination signaling, which specifically includes :

The UE signaling packet is decapsulated according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.
The relay function-enabled UE according to claim 31, wherein the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor is based on The second preset protocol group performs format encapsulation processing on the first destination signaling, and specifically includes:

The M first destination signaling is aggregated into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer to obtain P fifth intermediate signaling packets; the fifth intermediate signaling packet includes a relay protocol header, The relay protocol header includes S UE identifiers, respectively, the source UE identifiers of the S destination signalings constituting the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M ;

Each of the fourth intermediate signaling packets is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The UE with the relay function according to claim 31, wherein the number of the UE signaling packet and the first destination signaling is one, and the processor is based on the second preset protocol group The first destination signaling is used for format encapsulation processing, and specifically includes:

Performing a preset relay format encapsulation on the first destination signaling at the RRC protocol layer to obtain a sixth intermediate signaling packet; the sixth intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, where the UE identifier is a source UE identifier of the destination signaling;

The sixth intermediate signaling packet is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The relay function-enabled UE according to claim 29 or 32, wherein the aggregation rule is any one of the following rules:

Pre-set aggregation rules based on signaling sources; preset aggregation rules based on signaling types; preset aggregation rules based on logical channels/channel groups; one-to-one mapping rules in independent transmission.
A UE with a relay function, comprising: a communication bus, a network interface, a memory, and a processor, wherein:

The communication bus is configured to implement connection communication between the network interface, the memory, and the processor;

The network interface is configured to receive a node signaling packet from a mobile communication network node;

The network interface is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier;

The program stores a set of program codes, and the processor calls program code stored in the memory to perform the following operations:

Receiving a node signaling packet from a mobile communication network node;

Decapsulating the node signaling packet by using a third preset protocol group, and obtaining a second destination signaling and a destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes an RRC protocol ;

When the UE corresponding to the target UE identifier is a UE other than the first electronic device, the second destination signaling and the destination UE identifier are format-encapsulated based on the fourth preset protocol group, and the second purpose is obtained. Signaling packet

And sending the second destination signaling packet to the destination UE corresponding to the destination UE identifier.
The UE with relay function according to claim 35, wherein the processor further performs the following operations:

When the UE corresponding to the target UE identifier is the first electronic device, the second destination signaling is used as the second destination signaling packet to be sent.
The UE with the relay function according to claim 36, wherein the node signaling packet includes K signaling and K destination UE identifiers corresponding to the K signalings, K is greater than a natural number of 1; the processor performs decapsulation processing on the node signaling packet based on the third preset protocol group, and obtains the second destination signaling and the destination UE identifier corresponding to the second destination signaling, specifically including :

The node is in turn according to PHY protocol, MAC protocol, RLC protocol, PDCP and RRC protocol The signaling packet performs decapsulation;

Decapsulating the demodulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.
The UE with a relay function according to claim 37, wherein the node data includes a signaling and a destination UE identifier corresponding to the signaling, and the processor is based on a third preset protocol group. Decapsulating the node signaling packet, and obtaining the second destination signaling and the destination UE identifier corresponding to the second destination signaling, specifically:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling.
A UE with a relay function, comprising: a communication bus, a first network interface, a second network interface, a memory, and a processor, wherein:

The communication bus is configured to implement connection communication between the first network interface, the second network interface, the memory, and the processor;

The first network interface is configured to receive a UE signaling packet from the user equipment UE;

The first network interface is further configured to send the first destination signaling packet to the mobile communication network node;

The second network interface is configured to receive a node signaling packet from a mobile communication network node;

The second network interface is further configured to send the second destination signaling packet to the destination UE corresponding to the target UE identifier;

The program stores a set of program codes, and the processor calls program code stored in the memory to perform the following operations:

Receiving a UE signaling packet from the user equipment UE;

When the UE is a UE other than the first user equipment, decapsulating the UE signaling packet according to the first preset protocol group, to obtain a first destination signaling;

Performing format encapsulation processing on the first destination signaling according to the second preset protocol group, to obtain a first destination signaling packet; the first preset protocol group or the second preset protocol group includes radio resource control RRC protocol;

Transmitting the first destination signaling packet to a mobile communication network node;

Receiving a node signaling packet from a mobile communication network node;

Decapsulating the node signaling packet by using a third preset protocol group, and obtaining a second destination signaling and a destination UE identifier corresponding to the second destination signaling, where the third preset protocol group includes an RRC protocol ;

When the UE corresponding to the target UE identifier is a UE other than the first electronic device, the second destination signaling and the destination UE identifier are format-encapsulated based on the fourth preset protocol group, and the second purpose is obtained. Signaling packet

And sending the second destination signaling packet to the destination UE corresponding to the destination UE identifier.
The UE with relay function according to claim 39, wherein the processor further performs the following operations:

When the UE is the first user equipment, the UE signaling packet received from the first user equipment is used as the first destination signaling.
The UE with the relay function according to claim 40, wherein the processor performs decapsulation processing on the UE signaling packet based on the first preset protocol group, to obtain the first destination signaling, which specifically includes :

The UE signaling packet is decapsulated according to the physical layer PHY protocol, the medium access control layer MAC protocol, the radio link control layer RLC protocol, the packet data convergence protocol PDCP, and the radio resource control RRC protocol, to obtain the first destination signaling. .
The relay function-enabled UE according to claim 41, wherein the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor is based on The second preset protocol group performs format encapsulation processing on the first destination signaling, and specifically includes:

According to a preset aggregation rule, the M first destination signalings are aggregated into P first intermediate signaling packets, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation for each of the first intermediate signaling packets to obtain P second intermediate signaling packets; the second intermediate signaling packet includes a relay protocol header, and the relay protocol header The S UE identifiers are respectively the source UE identifiers of the S destination signalings that constitute the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M;

Each of the second intermediate signaling packets is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The UE with the relay function according to claim 41, wherein the number of the UE signaling packet and the first destination signaling is one, and the processor is based on the second preset protocol group Description The first destination signaling performs format encapsulation processing, and specifically includes:

Performing a preset relay format encapsulation on the first destination signaling to obtain a third intermediate signaling packet; the third intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, The UE identifier is a source UE identifier of the destination signaling;

The third intermediate signaling packet is format-encapsulated according to the RRC protocol, the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The UE with the relay function according to claim 40, wherein the processor performs decapsulation processing on the UE signaling packet based on the first preset protocol group, to obtain the first destination signaling, which specifically includes :

The UE signaling packet is decapsulated according to the PHY protocol, the MAC protocol, the RLC protocol, and the PDCP, to obtain the first destination signaling.
The relay function-enabled UE according to claim 44, wherein the number of the UE signaling packet and the first destination signaling is M, and M is a natural number greater than 1, the processor is based on The second preset protocol group performs format encapsulation processing on the first destination signaling, and specifically includes:

The M first destination signaling is aggregated into P fourth intermediate signaling packets according to a preset aggregation rule, where P is a natural number not less than 1, and P≤M;

Performing preset relay format encapsulation on each of the fourth intermediate signaling packets at the RRC protocol layer to obtain P fifth intermediate signaling packets; the fifth intermediate signaling packet includes a relay protocol header, The relay protocol header includes S UE identifiers, respectively, the source UE identifiers of the S destination signalings constituting the first intermediate signaling packet, and S is a natural number not less than 1, and S≤M ;

Each of the fourth intermediate signaling packets is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain P first destination signaling packets.
The UE with the relay function according to claim 44, wherein the number of the UE signaling packet and the first destination signaling is one, and the processor is based on the second preset protocol group The first destination signaling is used for format encapsulation processing, and specifically includes:

Performing a preset relay format encapsulation on the first destination signaling at the RRC protocol layer to obtain a sixth intermediate signaling packet; the sixth intermediate signaling packet includes a relay protocol header, where the relay protocol header includes a UE identifier, where the UE identifier is a source UE identifier of the destination signaling;

The sixth intermediate signaling packet is format-encapsulated according to the PDCP, the RLC protocol, the MAC protocol, and the PHY protocol, to obtain a first destination signaling packet.
The relay function-enabled UE according to claim 42 or 45, wherein the aggregation rule is any one of the following rules:

Pre-set aggregation rules based on signaling sources; preset aggregation rules based on signaling types; preset aggregation rules based on logical channels/channel groups; one-to-one mapping rules in independent transmission.
The UE with relay function according to claim 39, wherein the processor further performs the following operations:

When the UE corresponding to the target UE identifier is the first electronic device, the second destination signaling is used as the second destination signaling packet to be sent.
The UE with the relay function according to claim 48, wherein the node signaling packet includes K signaling and K destination UE identifiers corresponding to the K signalings, K is greater than a natural number of 1; the processor performs decapsulation processing on the node signaling packet based on the third preset protocol group, and obtains the second destination signaling and the destination UE identifier corresponding to the second destination signaling, specifically including :

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol;

Decapsulating the demodulated node signaling packet into K signaling and K destination UE identifiers corresponding to the K signaling one-to-one.
The UE with a relay function according to claim 39, wherein the node data includes a signaling and a destination UE identifier corresponding to the signaling, and the processor is based on a third preset protocol group. Decapsulating the node signaling packet, and obtaining the second destination signaling and the destination UE identifier corresponding to the second destination signaling, specifically:

Performing decapsulation on the node signaling packet according to the PHY protocol, the MAC protocol, the RLC protocol, the PDCP, and the RRC protocol, to obtain the signaling and the target UE identifier corresponding to the signaling.