WO2017000863A1 - 一种数据传输方法、无线网络节点和通信系统 - Google Patents
一种数据传输方法、无线网络节点和通信系统 Download PDFInfo
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- WO2017000863A1 WO2017000863A1 PCT/CN2016/087388 CN2016087388W WO2017000863A1 WO 2017000863 A1 WO2017000863 A1 WO 2017000863A1 CN 2016087388 W CN2016087388 W CN 2016087388W WO 2017000863 A1 WO2017000863 A1 WO 2017000863A1
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- data packet
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- H04W8/02—Processing of mobility data, e.g. registration information at HLR [Home Location Register] or VLR [Visitor Location Register]; Transfer of mobility data, e.g. between HLR, VLR or external networks
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Definitions
- the present invention relates to the field of communications, and in particular, to a data transmission method, a wireless network node, and a communication system.
- the C-RAN system is composed of a RRU (Remote Radio Unit, RRU for short) and a BBU pool.
- the BBU pool includes multiple BBUs (Base Band Units, BBUs).
- the RRUs and BBUs pass through the CPRI.
- the Common Public Radio Interface (CPRI) is connected.
- the current C-RAN scheme can effectively improve the system capacity, but the RRU and the BBU pool need a very ideal transmission network, that is, the CPRI needs an ideal bandwidth and delay, for example, a 20 MHz bandwidth cell supporting 8 antennas, and the baseband is 20 MHz bandwidth.
- the baseband sampling rate is 30.72M, and the sampling bit width is 15bit.
- a single antenna single sector needs a transmission rate of 1228.8M CPRI; if 8 antennas, it needs to be multiplied. 8, the transmission rate of 10Gbit / s.
- This high transmission rate is difficult to implement between the RRU and the BBU pool, so there is an urgent need for a solution that can reduce the transmission bandwidth and delay requirements.
- the technical problem to be solved by the embodiments of the present invention is to provide a data transmission method and a wireless network.
- the network node and the communication system can solve the problem of high transmission bandwidth and delay in the prior art.
- a first aspect of the embodiments of the present invention provides a data transmission method, including:
- the first wireless network node learns the bearer type of the downlink data packet
- the first radio network node sends the downlink data packet to a second radio network node, so that the second radio network node performs a PDCP layer on the downlink data packet.
- the first radio network node performs a PDCP layer function on the downlink data packet, and sends the processed downlink data packet to the second radio network node.
- the method further includes:
- the second wireless network node performs a PHY layer function, a MAC layer function, and an RLC layer on the uplink data packet.
- the bearer type of the uplink data packet is DRB;
- the first wireless network node performs a PDCP layer function on the uplink data packet, and sends the processed uplink data packet to the core network.
- the method further includes:
- the first wireless network node acquires DRB security information and SRB security information from the core network, the first wireless network node stores the DRB security information, and sends the SRB security information to the second wireless network node;
- the function of the first wireless network node to perform the PDCP layer on the downlink data packet includes:
- the first wireless network node performs a function of a PDCP layer on the downlink data packet according to the DRB security information.
- the SRB security information and the DRB security information include: an integrity protection algorithm, an integrity check algorithm, an encryption algorithm, One or more of a decryption algorithm and a security key.
- the method before the first wireless network node learns the bearer type of the downlink data packet, the method further includes:
- the first wireless network node returns a criterion for carrying the user equipment identifier to the second wireless network node, where the user equipment corresponding to the user equipment identifier has the right to access the second wireless network node.
- the admission indication is used to indicate that the user equipment establishes an SRB with the second wireless network node.
- the method further includes:
- the first wireless network node After the UE completes the handover operation, the first wireless network node transmits the service data to the UE via the target wireless access network node according to the transmission state parameter.
- the first wireless network node determines, from the set of wireless network nodes under the jurisdiction, other than the second wireless network node
- the target wireless network nodes include:
- the first wireless network node acquires a link quality parameter between each wireless network node in the wireless network node set and the user equipment, and selects a wireless network node with the best link quality parameter as the target wireless network node.
- the link quality parameter comprises one or more of RSRP, RSSI and RSRQ.
- a second aspect of the embodiments of the present invention provides a wireless network node, including:
- An identification module configured to learn the bearer type of the downlink data packet
- a first sending module configured to: when the bearer type is SRB, the first wireless network node sends the downlink data packet to a second wireless network node, so that the second wireless network node Describe the downlink data packet to perform the function of the PDCP layer;
- a first processing module configured to perform a PDCP layer function on the downlink data packet, and send the processed downlink data packet to the second wireless network section, where the bearer type is DRB point.
- the method further includes:
- a receiving module configured to receive an uplink data packet sent by the second wireless network node, where the uplink data packet performs a function of a PHY layer, a function of a MAC layer, and a function of an RLC layer in the second wireless network node, where
- the bearer type of the uplink data packet is DRB;
- the second processing module is configured to perform a function of the PDCP layer on the uplink data packet, and send the processed uplink data packet to the core network.
- the method further includes:
- a security information obtaining module configured to acquire DRB security information and SRB security information from the core network, where the first wireless network node stores the DRB security information, and sends the SRB security information to the second wireless network node;
- the first processing module is configured to perform a function of a PDCP layer on the downlink data packet according to the DRB security information.
- the SRB security information and the DRB security information include: an integrity protection algorithm, an integrity check algorithm, an encryption algorithm, One or more of a decryption algorithm and a security key.
- the method further includes:
- An SRB establishing module configured to receive a user equipment identifier and a connection request sent by the second wireless network node; where the user equipment corresponding to the user equipment identifier has the right to access the second wireless network node, And the second wireless network node returns an admission indication that carries the user equipment identifier, where the admission indication is used to indicate that the user equipment and the second wireless network node establish an SRB.
- the method further includes:
- a switching module configured to determine, from a set of radio network nodes under the jurisdiction, a target wireless network node other than the second wireless network node, and the target wireless network node, if the UE meets a handover condition
- the identifier is sent to the second wireless network node; the transmission state parameter of the service data is obtained from the second wireless network node; after the UE completes the handover operation, according to the transmission
- the status parameter transmits traffic data to the UE via the target wireless network node.
- the switching module is configured to acquire a chain between each wireless network node in the wireless network node set and the user equipment And a radio quality node that selects an optimal link quality parameter as the target radio network node, where the link quality parameter includes one or more of RSRP, RSSI, and RSRQ.
- a third aspect of the embodiments of the present invention provides a wireless network node, including a memory and a processor, wherein the memory stores instructions for implementing any one of the data transmission methods of the first aspect, and the processor invokes The instruction in the memory is executed to implement the data transmission method according to any one of the first aspects.
- a fourth aspect of the embodiments of the present invention provides a storage medium for controlling a computer device to perform a data transmission method, where the method includes the following steps:
- the bearer type is a signaling radio bearer SRB
- the downlink data packet to a second radio network node, so that the second radio network node performs a packet data convergence protocol PDCP on the downlink data packet.
- Layer function or
- the bearer type is a data radio bearer DRB
- performing a function of a PDCP layer on the downlink data packet and sending the processed downlink data packet to the second radio network node.
- a fifth aspect of the embodiments of the present invention provides a data transmission method, including:
- the second wireless network node learns the bearer type of the uplink data packet sent by the user equipment
- the second radio network node performs a function of a PHY layer and a function of an upper layer of the PHY layer on the uplink data packet;
- the second radio network node performs a function of a PHY layer, a function of a MAC layer, and a function of an RLC layer on the uplink data packet, and sends the processed uplink data packet to the uplink data packet.
- a first wireless network node configured to enable the first wireless network node to perform a PDCP layer function on the processed uplink data packet.
- the performing, by the second wireless network node, the function of performing the PHY layer on the uplink data packet and the function of the upper layer of the PHY layer includes:
- the method further includes:
- the fifth radio network node receives the downlink data packet sent by the first radio network node, where the bearer type of the downlink data packet is SRB;
- the second radio network node performs the functions of the RRC layer and the functions of the RRC layer on the downlink data packet, and sends the processed downlink data packet to the user equipment.
- the method further includes:
- the second wireless network node receives an admission indication that is generated by the first wireless network node after determining that the user equipment has an access right, where the admission indication carries the user equipment identifier;
- the second wireless network node generates a connection establishment message according to the admission indication, and sends the connection establishment message to the user equipment, so that the user equipment establishes an SRB according to the connection establishment message, and succeeds After the SRB is established, returning a connection establishment complete message to the second wireless network node;
- the second wireless network node sends the received connection setup complete message to the first wireless network node.
- the method further includes:
- the second wireless network node forwards the handover command message to the user equipment, where the handover command message carries the SRB security information, so that the user equipment sends the handover operation to the target wireless network.
- the node returns a handover complete message, and after receiving the handover complete message, the target wireless network access node performs security protection on the signaling data according to the SRB security information.
- determining that the target wireless network node to be switched includes :
- the second wireless network node determines that the user equipment meets a handover condition if a signal carrier level of the user equipment is less than a first threshold; or
- the second wireless network node receives an identity identifier that is sent by the first wireless network node and carries the target wireless network node, and determines the target network cable network node according to the identity identifier.
- a wireless network node includes:
- An identification module configured to learn the bearer type of the uplink data packet sent by the user equipment
- a first processing module configured to perform a function of a PHY layer and a function of an upper layer of the PHY layer on the uplink data packet if the bearer type is SRB;
- a first sending module configured to perform a PHY layer function, a MAC layer function, and an RLC layer function on the uplink data packet, and send the processed uplink data packet to the uplink data packet, where the bearer type is DRB a first wireless network node, configured to enable the first wireless network node to perform a PDCP layer function on the processed uplink data packet.
- the first processing module is configured to receive the SRB security information sent by the first radio network node, and perform the uplink data packet according to the SRB security information.
- the function of the PDCP layer is configured to perform the uplink data packet according to the SRB security information.
- the method further includes:
- a receiving module configured to receive a downlink data packet sent by the first wireless network node, where the bearer data type of the downlink data packet is SRB;
- the second processing module is configured to perform the functions of the RRC layer and the functions of the RRC layer on the downlink data packet, and send the processed downlink data packet to the user equipment.
- the method further includes:
- An SRB establishing module configured to forward, by the user equipment, a connection request that carries the user equipment identifier to the first wireless network node, and receive the first wireless network node to generate, after determining that the user equipment has access rights,
- the admission indication wherein the admission indication carries the user equipment identifier; generates a connection establishment message according to the admission indication, and sends the connection establishment message to the user equipment, so that the user equipment Establishing an SRB according to the connection setup message, and returning a connection establishment complete message to the second wireless network node after successfully establishing the SRB; and sending the received connection establishment complete message to the first wireless network node.
- the method further includes:
- a switching module configured to: determine, in a case that the user equipment meets a handover condition, a target wireless network node to be switched; and send, to the target wireless network node, a handover request message that carries the SRB security information, to enable the target
- the radio network node is ready to switch resources, return a handover command message to the second radio network node; and forward the handover command message to the user equipment, where the handover command message carries the SRB security information
- the target wireless network access node performs signaling data according to the SRB security information. safety protection.
- the switching module is configured to:
- a seventh aspect of the embodiments of the present invention provides a wireless network node, including a memory and a processor, wherein the memory stores the data transmission method according to any one of the fifth aspects.
- An instruction, the processor retrieving and executing an instruction in the memory, implementing the data transmission method according to any one of the fifth aspects.
- An eighth aspect of the embodiments of the present invention provides a storage medium for controlling a computer device to perform a data transmission method, where the method includes the following steps:
- the bearer type is SRB
- the bearer type is DRB
- a ninth aspect of the embodiments of the present invention provides a data transmission method, including:
- the first wireless network node Receiving, by the first wireless network node, an uplink data packet sent by the second wireless network device, where the uplink data packet carries first indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the first wireless network node performs a function of a PDCP layer on the uplink data packet.
- the function of the first radio network node to complete the PDCP layer on the uplink data packet includes:
- the first wireless network node learns the bearer type of the uplink data packet
- the bearer type of the uplink data packet is the DRB, perform the function of the PDCP layer on the second data packet according to the DRB security information, and send the processed uplink data packet to the core network;
- the bearer type of the uplink data packet is SRB
- the function of the PDCP layer and the function of the RRC layer are performed on the second data packet according to the SRB security information.
- the method further includes:
- the first wireless network node receives the downlink data packet sent by the core network, where the downlink data packet carries identity information indicating the user equipment, type information of the bearer, and identity information of the bearer. Second indication information;
- the first wireless network node performs the functions of the RRC layer and the function of the PDCP layer on the data packet, and sends the processed downlink data packet to the second wireless network node, so that the second wireless network node Obtaining, according to the second indication information, a user equipment, a bearer type, and a bearer of the downlink data packet.
- the method further includes:
- the first wireless network node determines a target wireless network node to be handed over and acquires UE context information of the second wireless network node, where the user equipment meets a handover condition;
- the method further includes:
- the first wireless network node determines a target wireless network node to be handed over;
- the handover indication message that carries the identifier of the target radio network node to the second radio network node, where the handover indication message is used to instruct the radio network node to acquire the UE of the user equipment Context information, and transmitting, to the first wireless network node, a handover request message carrying the UE context information;
- the wireless network node Sending, by the first wireless network node, a handover request message to the target wireless network node according to the handover request message, so that the target wireless network node, after determining that the user equipment has access rights, to the first
- the wireless network node returns a handover response message
- the first wireless network node After receiving the handover response message returned by the target wireless network node, the first wireless network node sends the handover response message to the second wireless network node, so that the wireless network node according to the handover response message Sending a handover command message to the user equipment, where the handover command is cancelled
- the information is used to instruct the user equipment to complete the handover operation.
- a tenth aspect of the embodiments of the present invention provides a wireless network node, including:
- a first receiving module configured to receive an uplink data packet sent by the second wireless network device, where the uplink data packet carries first indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- An identification module configured to learn, according to the first indication information, a user equipment, a bearer type, and a bearer corresponding to the uplink data packet;
- the first processing module is configured to perform a function of a PDCP layer on the uplink data packet.
- the first processing module is configured to learn a bearer type of the uplink data packet
- the bearer type of the uplink data packet is the DRB, perform the function of the PDCP layer on the second data packet according to the DRB security information, and send the processed uplink data packet to the core network;
- the bearer type of the uplink data packet is SRB
- the function of the PDCP layer and the function of the RRC layer are performed on the second data packet according to the SRB security information.
- the method further includes:
- a second receiving module configured to receive a downlink data packet sent by the core network, where the downlink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- a second processing module configured to perform a function of an RRC layer and a function of a PDCP layer on the data packet, and send the processed downlink data packet to the second wireless network node, so that the second wireless network node Obtaining, according to the second indication information, a user equipment, a bearer type, and a bearer of the downlink data packet.
- the method further includes:
- a first switching module configured to determine a target wireless network node to be switched and acquire UE context information of the second wireless network node, if the user equipment meets a handover condition
- the handover The command message is used to instruct the user equipment to complete the handover operation.
- the method further includes:
- a second switching module configured to determine a target wireless network node to be switched if the UE meets a handover condition
- the target wireless network node After receiving the handover response message returned by the target wireless network node, sending the handover response message to the second wireless network node, so that the wireless network node sends a handover to the user equipment according to the handover response message. And a command message, where the handover command message is used to instruct the user equipment to complete a handover operation.
- An eleventh aspect of the present invention provides a wireless network node, including a memory and a processor, wherein the memory stores an instruction for implementing the data transmission method according to any one of the ninth aspects, The processor retrieves and executes the instructions in the memory to implement the data transmission method of any of the ninth aspects.
- a twelfth aspect of the embodiments of the present invention provides a storage medium for controlling a computer device to perform a data transmission method, where the method includes the following steps:
- the uplink data packet carries first indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the function of the PDCP layer is performed on the uplink data packet.
- a thirteenth aspect of the embodiments of the present invention provides a data transmission method, including:
- the downlink data packet sent by the first wireless network node, where the downlink data packet carries first indication information that identifies the identity information of the user equipment, the type information of the bearer, and the identity information of the bearer;
- the second wireless network node performs the functions of the following layers of the PDCP layer on the downlink data packet.
- the method further includes:
- the second wireless network node Receiving, by the second wireless network node, an uplink data packet sent by the user equipment, where the uplink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the second wireless network node Performing, by the second wireless network node, a function of a layer of the PDCP layer on the uplink data packet, and sending the processed uplink data packet to the first wireless network node, so that the first wireless network node pair
- the processed uplink packet performs the function of the PDCP layer.
- the method further includes:
- the second wireless network node After receiving the handover indication carrying the identity identifier of the target wireless network node, the second wireless network node acquires UE context information of the user equipment and sends the UE context to the first wireless network node.
- the message switching request message After receiving the handover indication carrying the identity identifier of the target wireless network node, the second wireless network node acquires UE context information of the user equipment and sends the UE context to the first wireless network node.
- the message switching request message After receiving the handover indication carrying the identity identifier of the target wireless network node, the second wireless network node acquires UE context information of the user equipment and sends the UE context to the first wireless network node.
- a fourteenth aspect of the embodiments of the present invention provides a wireless network node, including:
- a first receiving module configured to receive a downlink data packet sent by the first wireless network node, where the downlink data packet carries first indication information that identifies identity information of the user equipment, type information of the bearer, and identity information of the bearer.
- An identification module configured to learn, according to the first indication information, a user setting corresponding to the downlink data packet Standby, bearer type and bearer;
- the first processing module is configured to perform the function of the following layer of the PDCP layer on the downlink data packet.
- the method further includes:
- a second receiving module configured to receive an uplink data packet sent by the user equipment, where the uplink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- a second processing module configured to perform a function of a layer of the PDCP layer on the uplink data packet, and send the processed uplink data packet to the first wireless network node, so that the first wireless network node pair
- the processed uplink packet performs the function of the PDCP layer.
- the method further includes:
- a switching module configured to forward the measurement report sent by the user equipment to the first wireless network node, so that the first wireless network node, according to the measurement report, is that the user equipment meets a handover condition, Determining, by the first wireless network node, a target wireless network node to be handed over, the first wireless network node returning, to the second wireless network node, a handover indication carrying an identity of the target wireless network node;
- a wireless network node comprising: a memory and a processor, wherein the memory stores an instruction for implementing the data transmission method according to any one of the third aspects, The processor is operative to retrieve and execute instructions in the memory to implement the data transmission method of any of the third aspects.
- a storage medium for controlling a computer device to perform a gesture control method comprising the steps of:
- the first wireless network node Receiving, by the first wireless network node, a downlink data packet, where the downlink data packet carries first indication information that identifies identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the functions of the following layers of the PDCP layer are performed on the downlink data packet.
- the first wireless network node is responsible for security protection of the service data carried in the DRB, and the wireless network node is responsible for performing signaling data carried in the SRB by performing re-division of each layer in the first wireless network node and the second wireless network node.
- Security protection; or the first wireless network node is responsible for the RRC layer and the PDCP layer processing, and the second wireless network node is responsible for the processing of the lower layer of the PDCP.
- FIG. 1 is a schematic structural diagram of a network according to an embodiment of the present invention.
- FIG. 2 is a schematic structural diagram of a base station according to an embodiment of the present invention.
- FIG. 3 is another schematic structural diagram of a base station according to an embodiment of the present invention.
- FIG. 4 is a schematic flowchart of a data transmission method according to a first embodiment of the present invention.
- FIG. 5 is a schematic flowchart diagram of a data transmission method according to a second embodiment of the present invention.
- FIG. 6 is a schematic flowchart of a data transmission method according to a third embodiment of the present invention.
- FIG. 7 is a schematic flowchart of a UE handover method according to a first embodiment of the present invention.
- FIG. 8 is a schematic flowchart of a data transmission method according to a fourth embodiment of the present invention.
- FIG. 9 is a schematic flowchart of a data transmission method according to a fifth embodiment of the present invention.
- FIG. 10 is a schematic flowchart diagram of a data transmission method according to a sixth embodiment of the present invention.
- FIG. 11 is a schematic flowchart diagram of a UE handover method according to a second embodiment of the present invention.
- FIG. 12 is a schematic flowchart of a UE handover method according to a third embodiment of the present invention.
- FIG. 13 is a schematic structural diagram of a wireless network node according to a first embodiment of the present invention.
- FIG. 14 is a schematic structural diagram of a wireless network node according to a second embodiment of the present invention.
- 15 is a schematic structural diagram of a wireless network node according to a third embodiment of the present invention.
- 16 is a schematic structural diagram of a wireless network node according to a fourth embodiment of the present invention.
- FIG. 17 is a schematic structural diagram of a wireless network node according to a fifth embodiment of the present invention.
- FIG. 18 is a schematic structural diagram of a wireless network node according to a sixth embodiment of the present invention.
- FIG. 19 is a schematic structural diagram of a wireless network node according to a seventh embodiment of the present invention.
- FIG. 20 is a schematic structural diagram of a wireless network node according to an eighth embodiment of the present invention.
- LTE Long Term Evolution
- the access network includes an RC and a RAP cluster, and an RC (Radio Access Network Controller).
- the RAP Radio Access Point, Radio Access Point, RAP for short
- the RAP cluster contains at least one RAP
- the RC and the RAP cluster are connected by TN (Transportation Network, TN).
- At least one RAP in the UE and the RAP cluster is connected; the RC is connected to the core network through an S1 interface, and the core network includes a mobility management entity MME, a serving gateway SGW, and a data gateway PGW, and the control plane of the core network is separated from the user plane, where The control plane MME and the RC are connected through an S1-MME interface, and are connected between the user plane SGW and the RC through an S1-U interface.
- the RC and the RAP clusters are the equivalent of the eNodeB (evolved Node B) in the LTE network architecture.
- the RC and the eNodeB are connected through the X2 interface.
- the eNodeB and the core network are connected through the S1 interface.
- One RAP in the cluster accesses the core network.
- the present invention can also be applied to GSM (Global System of Mobile communication) or CDMA (Code Division Multiple Access), or can be WCDMA (Wideband Code Division Multiple). Access, Wideband Code Division Multiple Access, or future 5G network standards, or Wireless Local Area Networks (WLAN), Worldwide Interoperability for Other communication formats such as Microwave Access, WiMAX, Bluetooth and Infrared.
- GSM Global System of Mobile communication
- CDMA Code Division Multiple Access
- WCDMA Wideband Code Division Multiple Access
- Access Wideband Code Division Multiple Access
- 5G network standards Fifth Generation
- WLAN Wireless Local Area Networks
- Worldwide Interoperability for Other communication formats such as Microwave Access, WiMAX, Bluetooth and Infrared.
- FIG. 2 is a schematic structural diagram of a base station according to an embodiment of the present invention.
- an evolved base station includes a first wireless network node and a wireless network node, where the first wireless network node includes a first RRC (Radio Resource).
- RRC Radio Resource
- the radio network node includes a second RRC sub-layer, a second PDCP sub-layer, RLC (Radio Link Control, Radio Link Control, RLC for short) layer, MAC (Media Access Control, Media Access Control, MAC) layer, and PHY (Physical, Physical, PHY for short) corresponding functions, of which, first The RRC sublayer and the second RRC sub-combination together form an RRC layer, the function of the first RRC sublayer is for global RRC configuration management, and the function of the second RRC sublayer is for SRB (Signaling Radio Bearers, signaling radio bearers, SRB) generation, transmission, reception, and local RRC configuration management.
- RRC Radio Resource Control
- SRB Signaling radio bearers
- the function of the first PDCP sublayer is used for DRB (Data Radio Bearers, Data Radio Bearers, DRB for short).
- PDCP function of the second sub-layer process for the SRB is used for DRB (Data Radio Bearers, Data Radio Bearers, DRB for short).
- the base station structure of the embodiment of the present invention is compared with the remote interface in the remote RRH (Remote Radio Head, RRH) remote mode, and the amount of data transmitted by the interface transmitted between the RC and the RAP is relatively Less, it is beneficial to reduce the amount of data exchanged between the RC (Radio Access Network Controller, RC) and the RAP (Radio Access Point, RAP for short), thereby reducing the transmission bandwidth and Delay requirements.
- RC Radio Access Network Controller
- RAP Radio Access Point
- FIG. 3 is a schematic structural diagram of a base station according to an embodiment of the present invention.
- an evolved base station includes a first wireless network node and a second wireless network node, where the first wireless network node includes an RRC layer and a PDCP.
- the layer is used to complete the functions corresponding to the RRC layer and the PDCP layer;
- the wireless network node includes an RLC layer, a MAC layer, and a PHY layer, and is used to perform functions corresponding to the RLC layer, the MAC layer, and the PHY layer.
- the functions corresponding to the PDCP layer include: header compression, security, and reordering; the functions corresponding to the RLC layer include splitting, cascading, and automatic repeat request (ARQ); the corresponding functions of the MAC layer include: scheduling, Logical channel priority processing, HARQ (Hybrid Automatic Repeat Request), etc.; PHY layer corresponding functions include: modulation and demodulation, coding, multi-antenna mapping.
- the structure of the base station in the embodiment of the present invention is relatively smaller than the remote interface in the existing RRH remote mode, and the interface transmitted between the RC and the RAP transmits less data, which is beneficial to reduce the relationship between the RC and the RAP. The amount of data that is exchanged, thereby reducing the transmission bandwidth and latency requirements.
- FIG. 4 is a schematic flowchart of a data transmission method according to a first embodiment of the present invention.
- a data protection method according to an embodiment of the present invention is implemented by using the network architecture of FIG. Methods include:
- the first wireless network node learns the bearer type of the downlink data packet.
- the first wireless network node receives the downlink data packet sent by the core network, and the bearer type of the downlink data packet is divided into SRB and DRB, that is, the downlink data packet is divided into service data and signaling data, and the first wireless network node may be configured according to
- the bearer type identifier carried in the downlink data packet is used to learn the bearer type of the downlink data packet.
- the first radio network node sends the downlink data packet to a second radio network node, so that the second radio network node performs the downlink data packet.
- PDCP layer processing If the bearer type is SRB, the first radio network node sends the downlink data packet to a second radio network node, so that the second radio network node performs the downlink data packet.
- the first wireless network node does not process the signaling data, and the first wireless network node forwards the downlink data packet to the second wireless network node.
- the RRC layer of the downlink data packet is learned by the second radio network node as the signaling data, and then the PDCP layer, the RLC layer, the MAC layer, and the PHY layer pair of the second radio network node respectively process the downlink data packet, where The second wireless network node sends the processed downlink data packet to the user equipment.
- the first radio network node performs PDCP layer processing on the downlink data packet, and sends the processed downlink data packet to the second radio network node.
- the first wireless network node performs PDCP layer processing on the downlink data packet, and the PDCP layer processing includes: one of header compression, security, and reordering.
- the first wireless network node sends the downlink data packet processed by the PDCP layer to the second wireless network node, and the second wireless network node continues the RLC layer processing, the MAC layer processing, and the PHY layer on the downlink data packet.
- the second wireless network node completes the foregoing processing, and sends the processed downlink data packet to the user equipment.
- the first wireless network node receives an uplink data packet sent by the second wireless network node, where the uplink data packet performs PHY layer processing, MAC layer processing, and RLC on the second wireless network node.
- Layer processing, and the bearer type of the uplink data packet is DRB;
- the first radio network node performs the PDCP layer processing on the uplink data packet, and then sends the uplink data packet to the core network.
- the second wireless network node is responsible for processing the signaling data
- the first wireless network node is responsible for processing the service data
- the second wireless network node receives the uplink data packet sent by the user equipment, and processes the uplink data packet through the PHY layer.
- the uplink data packet is sent to the first radio network node to continue the PDCP layer processing, and the first radio network node performs PDCP on the uplink data packet.
- the layer processing includes: performing security processing on the uplink data packet according to the obtained DRB security information.
- the method further includes: the first wireless network node acquiring DRB security information and SRB security information from the core network;
- Transmitting, by the first radio network node, the SRB security information to the second radio network node; performing, by the first radio network node, PDCP layer processing on the downlink data packet includes:
- the first radio network node performs PDCP layer processing on the downlink data packet according to the DRB security information.
- the first wireless network node performs the PDCP layer processing on the service data by using the DRB security information, that is, the data packet of the bearer type is the DRB, and the first wireless network node sends the SRB security information to the second wireless network node.
- the second wireless network node performs PDCP layer processing on the signaling data.
- the SRB security information and the DRB security information include at least one of the following: an integrity protection algorithm, an integrity check algorithm, an encryption algorithm, a decryption algorithm, and a security key.
- the integrity protection algorithm is used to add redundant information to the message to protect the message integrity.
- the integrity check algorithm is used to determine whether the message is changed according to the redundant information in the message.
- the encryption algorithm is used to encrypt the message to generate the ciphertext.
- the encryption key is used for encryption; the decryption algorithm is used to decrypt the ciphertext to generate plaintext, and the decryption key is used for decryption; the integrity protection algorithm and the integrity check algorithm can be the same algorithm, and the encryption algorithm and the decryption algorithm can also be The same algorithm; the key used for integrity protection, the key used for integrity check, the encryption key used for encryption, and the decryption key used for decryption can be the same security key or the same security Different security keys derived from the key.
- the SRB security information and the DRB security information can be obtained from the core network, or can be obtained from other network nodes, and the invention is not limited.
- the first wireless network node is responsible for security protection of the service data carried in the DRB, and the wireless network node is responsible for performing security protection on the signaling data carried in the SRB, and the two are divided to reduce the first wireless.
- the amount of data transmission between the network node and the wireless network node reduces the need for transmission bandwidth between the two, and can quickly complete the underlying configuration and maximize business continuity.
- FIG. 5 is a schematic flowchart of a data transmission method according to a second embodiment of the present invention.
- the method includes:
- the second radio network node learns the bearer type of the uplink data packet sent by the UE.
- the UE sends an uplink data packet to the second wireless network node, and the bearer type of the uplink data packet is divided into SRB or DRB, that is, the uplink data packet is divided into service data or signaling data, and the second wireless network node may be configured according to the uplink data packet.
- the bearer type identifier carried in the bearer knows the bearer type of the uplink data packet.
- the second radio network node performs PHY layer processing, MAC layer processing, RLC layer processing, PDCP layer processing, and RRC layer processing on the uplink data packet.
- the second wireless network node completes the PHY layer processing, the MAC layer processing, the RLC layer processing, the PDCP layer processing, and the RRC on the uplink data packet.
- Layer processing after processing, generates RRC signaling.
- the performing, by the second wireless network node, the PDCP layer processing on the uplink data packet includes: using the SRB security information to perform security protection on the uplink data packet.
- the second radio network node sends the uplink data packet to the first radio network node, so that the first radio network node completes the uplink data packet.
- PDCP layer processing If the bearer type is DRB, the second radio network node sends the uplink data packet to the first radio network node, so that the first radio network node completes the uplink data packet.
- the second wireless network node does not perform PDCP layer processing on the service data, and the second wireless network node completes PHY layer processing, MAC layer for the uplink data packet.
- the processed uplink data packet is sent to the first wireless network node, and the first wireless network node continues to perform processing on the uplink data packet by the PDCP layer, where the PDCP layer processing includes: using DRB security Information protects upstream packets.
- the SRB security information and the DRB security information may be obtained by the first wireless network node from the core.
- the network access, the SRB security information and the DRB security information include at least one of the following: an integrity protection algorithm, an integrity check algorithm, an encryption algorithm, a decryption algorithm, and a security key, and the first wireless network node uses the DRB security information to the service data.
- the security protection is performed.
- the first wireless network node sends the SRB security information to the second wireless network node, and the second wireless network node performs security protection on the signaling data according to the SRB security information.
- the first wireless network node is responsible for security protection of the service data carried in the DRB, and the wireless network node is responsible for performing security protection on the signaling data carried in the SRB, and the two are divided to reduce the first wireless.
- the amount of data transmission between the network node and the wireless network node reduces the need for transmission bandwidth between the two, and can quickly complete the underlying configuration and maximize business continuity.
- the data protection method in the embodiment of the present invention is described in detail below by taking the RC as the first wireless network node and the RAP accessed by the UE as the wireless network node.
- FIG. 6 is a schematic flowchart of a data transmission method according to a third embodiment of the present invention.
- the data transmission method according to the embodiment of the present invention is implemented by using the architecture in FIG. 2, where the RC is used in the embodiment of the present invention.
- the RAP is a second wireless network node, and the method includes:
- the UE sends an RRC connection setup request message to the RAP, where the RRC connection request carries the UE identifier of the UE.
- the UE sends an RRC connection setup request message to the RAP, where the RRC connection setup request message is used to establish an RRC connection between the UE and the RAP.
- the RRC connection request is sent through the default SRB (SRB0), and the RRC connection request is used for the UE to establish an RRC connection with the network, and establish a new SRB, for example, SRB1, SRB2, and SRB3.
- the UE identifier may be an S-TMSI or a C-RNTI, etc., for identifying a unique identity of the UE.
- the RAP sends an RRC connection request and the UE identifier to the RC.
- the RC and the RAP are one-to-many correspondences, and the RAP uniquely corresponds to one RC.
- the RAP determines the RC according to the corresponding relationship, and sends the RRC connection request and the UE identifier to the RC, where the UE identifier may be included in the RRC connection request. .
- the RC performs admission control on the user equipment corresponding to the UE identifier.
- the RC determines whether the UE has the right to access the RAP. If the UE has the right to access the RAP, the S604 is performed.
- the method for determining whether the UE has the right to access the RAP may be: The RC determines whether the UE has the right to access the RAP according to one or more of the load state parameter of the RAP and the surrounding RAP, the interference state parameter, the service type information of the UE, and the subscription information of the UE. For example, the load of the RAP is too high, and the access level of the UE in the subscription information of the UE is lower than the preset access level, and the RC rejects the UE accessing the RAP. Otherwise, the RC allows the UE to access the RAP.
- the RC returns an admission indication to the RAP, and carries a UE identifier.
- the admission indication message is used to indicate that the UE is allowed to access the RAP.
- the RAP sends an RRC connection setup message to the UE.
- the RAP receives the admission indication sent by the RC, and generates an RRC connection setup message, and sends the generated RRC connection setup message to the user equipment corresponding to the UE identifier.
- the UE establishes an RRC connection with the RAP. After the RRC connection is established, the UE returns an RRC connection setup complete message to the RAP.
- the UE After the UE successfully establishes an RRC connection, it indicates that the new SRB has been successfully established. The UE returns an RRC Connection Setup Complete message to the RAP for transmission in the new SRB.
- the UE returns an RRC connection setup complete message to the RAP.
- the RAP receives the RRC Connection Setup Complete message to learn that the new SRB is successfully established.
- the RAP returns an RRC connection establishment completion indication to the RC.
- the RC receives the RRC connection setup completion indication to obtain that the new SRB is successfully established.
- the initial context establishment process of the UE is triggered between S609, RC and the core network.
- the RC triggers the completion of the initial context establishment procedure of the UE. For example, the RC sends the UE initial context setup request message. After the UE initialization context establishment process is completed, the core network sends the UE context to the RC. information.
- S610 Send UE context information that carries DRB security information and SRB security information and/or QoS parameters of the DRB.
- the RC sends the DRB security information, the SRB security information, and the QoS parameters of the DRB to the RAP, and the RAP generates an RRC connection reconfiguration message according to one or more of the foregoing information, and is used to complete the DRB establishment of the UE and the SRB weight. Configuration and security activation.
- the RAP saves the SRB security information and the QoS parameters of the DRB.
- the UE context information includes: DRB security information, SRB security information, and QoS parameters of the DRB, and the DRB security information and the SRB security information include a security key, an encryption algorithm, a decryption algorithm, an integrity protection algorithm, and an integrity check algorithm.
- the DRB security information and the SRB security information may be the same, that is, the same security information is used for DRB and SRB for security protection.
- the QoS parameters represent quality of service requirements for traffic data transmitted in the DRB.
- the QoS parameters include a maximum transmission rate, a minimum guaranteed rate, or a transmission delay.
- the QoS parameters can be sent to the RC by the core network, and the RC adjusts the QoS parameters according to the load state parameters of the RAP and the surrounding RAP to generate new QoS parameters.
- the RC also triggers establishment of a DRB for the UE, reconfiguration of the SRB of the UE, and security configuration.
- the security protection process of the service data takes the downlink direction of the data transmission as an example: after the RC receives the service data sent by the core network, the RC completes the PDCP function of the service data, generates a PDCP PDU, and performs header compression on the PDCP PDU according to the encryption algorithm. Encrypt the PDCP PDU with the encryption key, add the serial number to the PDCP PDU, and send the PDCP PDU to the RAP.
- the RAP completes the functions corresponding to the RLC layer, the MAC layer, and the PHY layer of the PDCP PDU. For example, the RAP completes the PDCP. Segmentation, scheduling, modulation coding of the PDU, and performing quality of service control on the service data carried in the DRB according to the generated QoS parameters.
- the RC sends the SRB security information to the RAP.
- the RAP performs security protection on the signaling data carried in the SRB according to the SRB security information.
- the RAP performs security protection on the signaling data carried in the SRB, such as encryption, decryption, integrity protection, and integrity check, and signaling data such as RRC signaling.
- FIG. 7 is a schematic flowchart of a UE handover method according to a first embodiment of the present invention.
- the method includes:
- the UE accesses the source RAP, and the source RAP determines whether the UE meets the handover condition.
- the method may be: the source RAP determines, according to the received signal carrier level of the UE, the signal carrier level of the UE.
- the source RAP determines according to the received signal-to-interference ratio of the UE, when the signal-to-interference ratio of the UE is lower than a given value, The UE satisfies the handover condition; or the source RAP determines from the distance to the UE that when the distance between the source RAP and the UE is greater than a given value, it is determined that the UE satisfies the handover condition.
- the source RAP needs to obtain the target RAP to be switched by the UE when the handover condition is satisfied.
- the determination of the target RAP may be performed by the active RAP, or may be performed by the RC, which is not limited by the present invention.
- the source RAP acquires a target RAP to be switched to the RC.
- the selection of the target RAP is performed by the RC, and the source RAP sends a request for acquiring the target RAP to the corresponding RC, where the request is used to request the RC to select a target RAP other than the source RAP from its own RAP set.
- the RC determines the target RAP to be switched.
- the RC manages the RAP set, and the RAP set includes the RAP and the at least one other RAP.
- the RC can obtain the link state parameter between the RAP and the UE reported by the RAP, and the RC takes the RAP with the best link state parameter as The target RAP to be switched.
- the link state parameters include one or more of RSSI, RSRP, and RSRQ.
- the RC sends the identifier of the target RAP to the RAP.
- the source RAP obtains the SRB security information of the SRB, and sends a handover request message carrying the SRB security information to the target RAP.
- the source RAP obtains SRB security information of the SRB with the UE, and the security information includes one or more of a security key, an encryption algorithm, a decryption algorithm, an integrity protection algorithm, and an integrity check algorithm, and the source RAP
- the target RAP is determined according to the identifier of the target RAP, and a handover request message carrying the SRB security information is sent to the target RAP.
- S706 The target RAP prepares a handover resource, and after the handover preparation is completed, returns a handover command message to the source RAP.
- the handover resource includes a spectrum resource, a hardware resource, and the like
- the target RAP receives and saves the SRB security information of the source RAP, so that the target RAP uses the SRB security information to secure the SRB with the UE after the UE switches to the target RAP. Protection, the DRB security information of the DRB between the RC and the UE remains unchanged. After the UE switches to the target RAP, the RC continues to use the original DRB security information to secure the service data on the DRB.
- the target RAP sends a handover command message to the source RAP.
- the target RAP is ready to switch resource replacement, and sends a handover command message to the source RAP.
- the UE can perform the handover operation.
- the source RAP sends a handover command message to the UE.
- the UE performs a handover operation. After the UE performs the handover operation, it accesses the target RAP.
- the source RAP sends a transmission status parameter to the RC.
- the transmission status parameter may be a PDCP status report, and is divided into an uplink transmission status parameter and a downlink transmission status parameter.
- the transmission status parameter indicates the sequence number of the PDCP data packet that was successfully sent or not successfully transmitted to the UE, and the sequence number of the successfully transmitted PDCP data packet is taken as an example.
- the transmission status parameter indicates the sequence number of the PDCP data packet that is successfully or unsuccessfully sent to the RC, and the RC sends the uplink transmission status parameter to the UE.
- the UE is configured to send the PDCP data packet to the target RAP according to the serial number to avoid repeated transmission of the data.
- FIG. 8 is a schematic flowchart of a data transmission method according to a fourth embodiment of the present invention.
- the data transmission method of the embodiment of the present invention is implemented by using the structural diagram of FIG. 3, where the method includes:
- the first wireless network node receives an uplink data packet sent by the second wireless network device, where the uplink data packet carries first indication information indicating identity information of the UE, type information of the bearer, and identity information of the bearer.
- the second wireless network node receives the uplink data packet sent by the UE, where the uplink data packet carries the identity information of the UE, the type information of the bearer, and the identity information of the bearer, and the second wireless network node passes the uplink data packet to the PHY layer. Processing, MAC layer processing, and RLC layer processing, the processed uplink data packet is sent to the first wireless network node, and the processed uplink data packet carries the first information indicating the identity information of the UE, the type information of the bearer, and the identity information of the bearer. Instructions.
- the first radio network node learns, according to the first indication information, a user equipment, a bearer type, and a bearer corresponding to the uplink data packet.
- the first radio network node learns the user equipment, the bearer type, and the bearer corresponding to the uplink data packet according to the first indication information carried in the uplink data packet, and the bearer type is divided into SRB and DRB.
- the first indication information may be a GTP tunnel identifier.
- the first wireless network node performs PDCP layer processing on the uplink data packet.
- the first wireless network node performs uplink PDTP layer processing on the PDCP layer, where the PDCP layer is located.
- FIG. 9 is a schematic flowchart of a data protection method according to a fifth embodiment of the present invention.
- the method includes:
- the second radio network node receives the downlink data packet sent by the first radio network node, where the downlink data packet carries first indication information that identifies the identity information of the UE, the type information of the bearer, and the identity information of the bearer.
- the core network sends a downlink data packet to the first wireless network node, where the downlink data packet carries the identity information of the UE, the type information of the bearer, and the identity information of the bearer, and the first wireless network node can learn the uplink data packet by using the RRC layer.
- the type information of the bearer, the first radio network node performs PDCP layer processing on the uplink data packet, and sends the processed downlink data packet to the second radio network node, where the processed downlink data packet carries the identity information of the UE and the type of the bearer.
- First indication information of the information and the carried identity information First indication information of the information and the carried identity information.
- the second radio network node learns, according to the first indication information, a user equipment, a bearer type, and a bearer corresponding to the downlink data packet.
- the bearer type is divided into SRB and DRB, and different UEs correspond to different bearers.
- the second wireless network node performs RLC layer processing, MAC layer processing, and PHY layer processing on the downlink data packet.
- the second wireless network node performs the RLC layer processing, the MAC layer processing, and the PHY layer processing on the downlink data packet, and sends the processed downlink data packet to the corresponding user equipment according to the identity information of the UE.
- FIG. 10 is a schematic flowchart of a data transmission method according to a sixth embodiment of the present invention.
- an RC is a first wireless network node
- a RAP is a second wireless network node, where the method includes:
- S1001 The UE sends an RRC connection setup request message carrying the UE identifier to the RAP.
- the UE pre-establishes the default bearer SRB0, and the UE sends an RRC connection request through the SRB0.
- the RRC connection request is used to establish a new SRB for the UE, for example, SRB1, SRB2, or SRB3.
- the UE identifier is used to uniquely identify the identity of the UE, and the UE identifier. It can be S-TMSI or C-RNTI.
- the RAP receives an RRC connection setup request message, and allocates a first SRB identifier to the SRB to be established.
- the RAP allocates a first SRB identifier to the SRB to be established, and the first SRB identifier is used by the RAP to uniquely identify the identity of the SRB to be established (downlink direction), for example, a signaling message that can be transmitted in the SRB to be established.
- the GTP tunnel identifier is added as the first SRB identifier of the SRB to be established.
- the RAP can determine the SRB to be established by knowing the first SRB identifier in the downlink direction.
- the RAP locally saves the mapping relationship between the first SRB identifier and the UE identifier.
- the RAP sends an RRC connection request carrying the UE identifier and the first SRB identifier to the RC, and forwards the RRC connection request to the RC.
- the RAP adds the first SRB identifier and the UE identifier to the RRC connection request, and then sends the RRC connection request to the RC, where the RRC connection request is still sent to the RC through the default bearer SRB0.
- the RC performs admission control on the UE, and allows the UE to allocate the second SRB identifier after accessing the RAP, and generates SRB configuration information.
- the RC parses the UE identifier and the first SRB identifier from the received RRC connection request, and performs admission control on the user equipment corresponding to the UE identifier.
- the method for admission control may be: RC according to the load of the RAP and the surrounding RAP.
- One or more of the status parameter, the interference status parameter, the service type information of the UE, and the subscription information of the UE determine whether the UE has the right to access the RAP. For example, the load of the RAP is too high, and the access level of the UE in the subscription information of the UE is lower than the preset access level, and the RC rejects the UE accessing the RAP. Otherwise, the RC allows the UE to access the RAP.
- the RC determines that the UE has the right to access the RAP, and allocates a second SRB identifier to the SRB to be established.
- the second SRB identifier is used to uniquely identify the identity of the SRB to be established in the RC (upstream direction), and the RC saves the first SRB locally.
- the mapping relationship between the identifier, the second SRB identifier, and the UE identifier is used to uniquely identify the identity of the SRB to be established in the RC (upstream direction), and the RC saves the first SRB locally.
- the RC generates SRB configuration information, where the SRB configuration information includes the first SRB configuration information and the second SRB configuration information, where the first SRB configuration information is used to configure the RLC layer, the MAC layer, and the PHY layer of the RAP, and the second SRB
- the configuration information is used by the UE to configure the RRC layer, the PDCP layer, the RLC layer, the MAC layer, and the PHY layer.
- the UE establishes a new SRB.
- the first SRB configuration information and the second SRB configuration information may be distinguished by carrying different identifiers in the SRB configuration information, where the first SRB information is used for sending to the RAP, and the second SRB configuration information is used for sending to the UE.
- the RC sends an RRC connection setup message carrying the first SRB identifier, the second SRB identifier, and the SRB configuration information to the RAP.
- the RAP completes the bottom layer configuration according to the first SRB configuration information.
- the RAP parses the first SRB identifier, the second SRB identifier, and the SRB configuration information from the received RRC connection setup message, and the RAP learns the SRB to be established by the UE according to the first SRB identifier, and learns the SRB configuration information.
- An SRB configuration information is configured to configure the RLC layer, the MAC layer, and the PHY layer according to the first SRB configuration information.
- the RAP learns the second SRB configuration information in the SRB configuration information, and adds the second SRB configuration information to the RRC connection setup message.
- the first SRB configuration information or/and the second SRB configuration information includes a third SRB identifier, where the third SRB identifier is used to learn signaling data between the UE and the RAP.
- the RAP saves the relationship between the third SRB identifier and the first SRB identifier/second SRB identifier.
- the RAP sends an RRC connection setup message carrying the second SRB configuration information to the UE.
- the UE configures the RRC layer, the PDCP layer, the RLC layer, the MAC layer, and the PHY layer according to the second SRB configuration information to establish a new SRB (for example, SRB1), and the UE returns to the RAP after successfully establishing the SRB1.
- the RRC Connection Setup Complete message is sent by the new SRB1, and the RRC connection setup complete message carries the UE identifier.
- the UE sends an RRC connection setup complete message carrying the UE identifier to the RAP, to notify the RC that the new SRB is successfully established.
- the RAP sends an RRC connection setup complete message carrying the second SRB identifier to the RC.
- the third SRB identifier indicates the identifier of the second SRB configuration information, and the RAP queries the second SRB identifier according to the mapping relationship between the third SRB identifier and the second SRB identifier, and adds the second SRB identifier to the RRC connection setup complete message.
- the RC learns the new SRB of the UE according to the second SRB identifier.
- the initial context establishment process is triggered between the S1010, the RC, and the core network.
- the RC obtains the SRB security information of the newly established SRB, the DRB security information of the DRB to be established, and the QoS parameters of the DRB to be established from the core network through the initial context establishment process of the UE.
- S1011, RC acquires DRB security information, SRB security information, and QoS parameters of the DRB.
- the RC obtains the DRB security information of the DRB to be established, the SRB security information of the new SRB, and the security information of the DRB to be established, and the RC generates the DRB configuration information, and the DRB configuration information is classified into two types: the first DRB configuration.
- the information is configured on the RAP, and the second DRB configuration information is used to establish the DRB configuration on the UE, the second DRB configuration information, and the second DRB configuration.
- Information can be distinguished by different representations.
- the DRB to be established by the RC allocates a first DRB identifier, and is used by the RC to uniquely know the identity of the DRB of the UE.
- S1012 The RC sends the first DRB configuration information and the first DRB identifier.
- the RAP learns the first DRB configuration information, and performs DRB configuration on the RLC layer, the MAC layer, and the PHY layer according to the first DRB configuration information. After the RAP completes the DRB configuration, the second DRB identifier is allocated to the DRB, and the second DRB identifier is used in the RAP. The only one is the identity of the DRB of the UE. The RAP learns the second DRB configuration information in the DRB configuration information. The third DRB identifier is included in the first DRB configuration information and/or the second DRB configuration information, and the third DRB identifier is used to learn the DRB between the UE and the RAP.
- the RAP sends a DRB configuration complete message carrying the first DRB identifier and the second DRB identifier to the RC.
- the RC After receiving the DRB configuration complete message, the RC generates an RRC connection reconfiguration message, where the RRC connection reconfiguration message is used to instruct the UE to establish a DRB.
- the RC sends an RRC connection reconfiguration message carrying the first SRB identifier and the second DRB configuration information to the RAP.
- the RAP learns, according to the first SRB identifier, the UE to which the SRB belongs.
- the RAP sends an RRC connection reconfiguration message carrying the second DRB configuration information to the UE.
- the UE configures the DRB according to the second DRB configuration information, and establishes a DRB. After the DRB is successfully established, the UE returns an RRC connection reconfiguration complete message to the RAP, where the RRC connection reconfiguration message carries the identifier of the second SRB configuration message.
- the RAP sends an RRC connection reconfiguration complete message carrying the second SRB identifier to the RC.
- the RC secures the created SRB and DRB according to the SRB security information and the DRB security information.
- the RC sends the security-protected service data to the RAP, where the service data carries the first DRB identifier and the second DRB identifier, where the signaling data carries the first SRB identifier and the second SRB identifier, and in the uplink direction, the RC is based on the service data.
- the first DRB identifier carried in the information indicates that the service message belongs to the UE, and the signaling message belongs to the UE according to the second SRB identifier carried in the signaling data.
- FIG. 11 is a schematic flowchart of a UE handover method according to a second embodiment of the present invention.
- the method includes:
- S1101 The UE triggers a random access procedure, and a random access channel is established between the UE and the source RAP and the RC.
- the source RAP sends the UE context information to the RC.
- the UE context information includes C-RNTI or radio resource configuration information and the like.
- S1104 The UE performs RRM measurement.
- S1105 The UE sends a measurement report generated after performing the RRM measurement to the RAP.
- the source RAP sends a measurement report to the RC.
- S1107 The RC detects, according to the measurement report, whether the UE meets the handover condition. If yes, prepares the handover, and performs S1107, and the UE determines that the target RAP to be switched can be determined according to the measurement report.
- S1108 The RC sends a handover request message carrying the UE context information to the target RAP.
- S1109 The target RAP performs admission control on the UE, and determines whether the UE is allowed to access the target RAP. If the UE allows access to the target RAP, S1110 is performed.
- S1110 The target RAP returns a handover response message to the RC.
- RC sends a handover command message to the source RAP.
- S1112 Perform a handover operation, and the UE switches from the source RAP to the target RAP. After the handover succeeds, the target RAP uses the SRB security information in the UE context information to secure the signaling data, and uses the DRB security information to secure the service data. protection.
- FIG. 12 is a schematic flowchart of a UE handover method according to a third embodiment of the present invention.
- the method includes:
- S1201 The UE performs RRM measurement.
- S1202 The UE sends a measurement report that performs RRM generation to the RAP.
- the source RAP forwards the measurement report to the RC.
- S1204 The RC detects, according to the measurement report, whether the UE meets the handover condition. If yes, execute S705, and the RC determines the target RAP to be switched at the same time.
- S1205 The RC sends a handover indication carrying the identifier of the target RAP to the source RAP.
- S1206 The source RAP returns a handover request message carrying the identifier of the target RAP to the RC.
- S1207 The RC sends a handover request message carrying the UE context information to the target RAP.
- S1208 The target RAP performs admission control on the UE, and prepares the handover after the UE is allowed to access.
- S1209 The target RAP sends a handover response message to the RC.
- S1210 The RC sends a handover command message to the source RAP.
- the UE is switched from the source RAP to the target RAP.
- the target RAP uses the SRB security information in the UE context information to secure the signaling data, and uses the DRB security information to secure the service data.
- FIG. 13 is a schematic structural diagram of a wireless network node according to a first embodiment of the present invention.
- the wireless network node includes: an identification module 1301, a first sending module 1302, and a first processing module. 1303.
- the identification module 1301 is configured to learn the bearer type of the downlink data packet.
- the first sending module 1302 is configured to: when the bearer type is SRB, the first wireless network node sends the downlink data packet to a second wireless network node, so that the second wireless network node pair The downlink data packet performs the function of the PDCP layer.
- the first processing module 1303 is configured to perform a PDCP layer function on the downlink data packet when the bearer type is a DRB, and send the processed downlink data packet to the second wireless network node.
- the wireless network node of the embodiment of the present invention further includes:
- a receiving module configured to receive an uplink data packet sent by the second wireless network node, where the second wireless network node performs a PHY layer function, a MAC layer function, and an RLC layer function on the uplink data packet, where The bearer type of the uplink data packet is DRB;
- the second processing module is configured to perform a function of the PDCP layer on the uplink data packet, and send the processed uplink data packet to the core network.
- the wireless network node of the embodiment of the present invention further includes:
- a security information obtaining module configured to acquire DRB security information and SRB security information from the core network, where the first wireless network node stores the DRB security information, and sends the SRB security information to the second wireless network node;
- the first processing module is configured to perform a function of a PDCP layer on the downlink data packet according to the DRB security information.
- the SRB security information and the DRB security information include: a integrity protection algorithm, One or more of an integrity check algorithm, an encryption algorithm, a decryption algorithm, and a security key.
- the wireless network node of the embodiment of the present invention further includes:
- An SRB establishing module configured to receive a user equipment identifier and a connection request sent by the second wireless network node; where the user equipment corresponding to the user equipment identifier has the right to access the second wireless network node, And the second wireless network node returns an admission indication that carries the user equipment identifier, where the admission indication is used to indicate that the user equipment and the second wireless network node establish an SRB.
- the wireless network node of the embodiment of the present invention further includes:
- a switching module configured to determine, from a set of radio network nodes under the jurisdiction, a target wireless network node other than the second wireless network node, and the target wireless network node, if the UE meets a handover condition
- the identifier is sent to the second wireless network node; the transmission state parameter of the service data is obtained from the second wireless network node; after the UE completes the handover operation, the target wireless connection network is used according to the transmission state parameter
- the node transmits the service data with the UE.
- the switching module is configured to acquire a link quality parameter between each wireless network node in the wireless network node set and the user equipment, and select a wireless network node with the best link quality parameter as the target.
- a wireless network node wherein the link quality parameter comprises one or more of RSRP, RSSI, and RSRQ.
- a wireless network node includes: an identification module 1401, a first processing module 1402, and a first sending module 1403.
- An identification module configured to learn the bearer type of the uplink data packet sent by the user equipment
- a first processing module configured to perform a function of a PHY layer and a function of an upper layer of the PHY layer on the uplink data packet if the bearer type is SRB;
- a first sending module configured to perform a PHY layer function, a MAC layer function, and an RLC layer function on the uplink data packet, and send the processed uplink data packet to the uplink data packet, where the bearer type is DRB a first wireless network node, configured to enable the first wireless network node to perform a PDCP layer function on the processed uplink data packet.
- the first processing module is configured to receive the SRB sent by the first wireless network node.
- the security information performs a function of the PDCP layer on the uplink data packet according to the SRB security information.
- the wireless network node of the embodiment of the present invention further includes:
- a receiving module configured to receive a downlink data packet sent by the first wireless network node, where the bearer data type of the downlink data packet is SRB;
- the second processing module is configured to perform the functions of the RRC layer and the functions of the RRC layer on the downlink data packet, and send the processed downlink data packet to the user equipment.
- the wireless network node of the embodiment of the present invention further includes:
- An SRB establishing module configured to forward, by the user equipment, a connection request that carries the user equipment identifier to the first wireless network node, and receive the first wireless network node to generate, after determining that the user equipment has access rights,
- the admission indication wherein the admission indication carries the user equipment identifier; generates a connection establishment message according to the admission indication, and sends the connection establishment message to the user equipment, so that the user equipment Establishing an SRB according to the connection setup message, and returning a connection establishment complete message to the second wireless network node after successfully establishing the SRB; and sending the received connection establishment complete message to the first wireless network node.
- the wireless network node of the embodiment of the present invention further includes:
- a switching module configured to: determine, in a case that the user equipment meets a handover condition, a target wireless network node to be switched; and send, to the target wireless network node, a handover request message that carries the SRB security information, to enable the target
- the radio network node is ready to switch resources, return a handover command message to the second radio network node; and forward the handover command message to the user equipment, where the handover command message carries the SRB security information
- the target wireless network access node performs signaling data according to the SRB security information. safety protection.
- the switching module is configured to:
- a wireless network node includes: a first receiving module 1501, an identifying module 1502, and a first processing module 1503.
- the first receiving module 1501 is configured to receive an uplink data packet sent by the second wireless network device, where the uplink data packet carries first indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer. .
- the identification module 1502 is configured to learn, according to the first indication information, a user equipment, a bearer type, and a bearer corresponding to the uplink data packet.
- the first processing module 1503 is configured to perform a function of the PDCP layer on the uplink data packet.
- the first processing module is configured to learn a bearer type of the uplink data packet.
- the bearer type of the uplink data packet is the DRB, perform the function of the PDCP layer on the second data packet according to the DRB security information, and send the processed uplink data packet to the core network;
- the bearer type of the uplink data packet is SRB
- the function of the PDCP layer and the function of the RRC layer are performed on the second data packet according to the SRB security information.
- the wireless network node of the embodiment of the present invention further includes:
- a second receiving module configured to receive a downlink data packet sent by the core network, where the downlink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- a second processing module configured to perform a function of an RRC layer and a function of a PDCP layer on the data packet, and send the processed downlink data packet to the second wireless network node, so that the second wireless network node Obtaining, according to the second indication information, a user equipment, a bearer type, and a bearer of the downlink data packet.
- the wireless network node of the embodiment of the present invention further includes:
- a first switching module configured to determine a target wireless network node to be switched and acquire UE context information of the second wireless network node, if the user equipment meets a handover condition
- the handover The command message is used to instruct the user equipment to complete the handover operation.
- the wireless network node of the embodiment of the present invention further includes:
- a second switching module configured to determine a target wireless network node to be switched if the UE meets a handover condition
- the target wireless network node After receiving the handover response message returned by the target wireless network node, sending the handover response message to the second wireless network node, so that the wireless network node sends a handover to the user equipment according to the handover response message. And a command message, where the handover command message is used to instruct the user equipment to complete a handover operation.
- FIG. 16 is a schematic structural diagram of a wireless network node according to a fourth embodiment of the present invention.
- the wireless network node includes: a first receiving module 1601, an identifying module 1602, and a first processing module. 1603.
- the first receiving module 1601 is configured to receive a downlink data packet sent by the first wireless network node, where the downlink data packet carries a first indication that identifies identity information of the user equipment, type information of the bearer, and identity information of the bearer. information.
- the identification module 1602 is configured to learn, according to the first indication information, a user equipment, a bearer type, and a bearer corresponding to the downlink data packet.
- the first processing module 1603 is configured to perform the function of the following layer of the PDCP layer on the downlink data packet.
- the wireless network node of the embodiment of the present invention further includes:
- a second receiving module configured to receive an uplink data packet sent by the user equipment, where the uplink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- a second processing module configured to perform a function of a layer of the PDCP layer on the uplink data packet, and send the processed uplink data packet to the first wireless network node, so that the first wireless network node pair
- the processed uplink packet performs the function of the PDCP layer.
- the wireless network node of the embodiment of the present invention further includes:
- a switching module configured to forward the measurement report sent by the user equipment to the first wireless network node, so that the first wireless network node, according to the measurement report, is that the user equipment meets a handover condition, Determining, by the first wireless network node, a target wireless network node to be handed over, the first wireless network node returning, to the second wireless network node, a handover indication carrying an identity of the target wireless network node;
- a fifth embodiment of the present invention further provides a wireless network node.
- the wireless network node includes a processor 171, a memory 173, and a communication interface 172.
- Communication interface 172 is used to communicate with external devices.
- the number of processors in the wireless network node 17 may be one or more.
- processor 171, memory 173, and communication interface 172 may be connected by a bus or other means.
- the wireless network node can be used to perform the method illustrated in FIG. For the meaning and examples of the terms involved in the embodiment, reference may be made to the corresponding embodiment of FIG. I will not repeat them here.
- the program code is stored in the memory 173.
- the processor 171 is configured to call the program code stored in the memory 173 for performing the following operations:
- the bearer type is a signaling radio bearer SRB
- the downlink data packet to a second radio network node, so that the second radio network node performs a packet data convergence protocol PDCP on the downlink data packet.
- Layer function or
- the bearer type is a data radio bearer DRB
- performing a function of a PDCP layer on the downlink data packet and sending the processed downlink data packet to the second radio network node.
- the processor is further configured to:
- the second wireless network node Receiving, by the second wireless network node, an uplink data packet, where the second wireless network node performs a physical PHY layer function, a medium access control MAC layer function, and a logical link control RLC layer on the uplink data packet.
- the bearer type of the uplink data packet is DRB;
- the processor is further configured to:
- the functions of performing the PDCP layer on the downlink data packet include:
- the SRB security information and the DRB security information comprise one or more of a integrity protection algorithm, an integrity check algorithm, an encryption algorithm, a decryption algorithm, and a security key.
- the processor before the processor performs the learning of the bearer type of the downlink data packet, the processor is further configured to:
- the user equipment corresponding to the user equipment identifier has the right to access the second wireless network node, returning an admission indication carrying the user equipment identifier to the second wireless network node, where the access
- the indication is for indicating that the SRB is established between the user equipment and the second wireless network node.
- the processor is further configured to:
- the user equipment satisfies the handover condition, it is determined from the set of wireless network nodes under its jurisdiction Determining a target wireless network node other than the second wireless network node, and transmitting an identifier of the target wireless network node to the second wireless network node;
- the service data is transmitted to the user equipment via the target wireless access network node according to the transmission status parameter.
- the determining, by the processor, to determine a target wireless network node other than the second wireless network node from the set of wireless network nodes under management includes:
- the quality parameters include one or more of a reference signal received power RSRP, a received signal strength indicator RSSI, and a reference signal received quality RSRQ.
- a sixth embodiment of the present invention further provides a wireless network node.
- the wireless network node includes a processor 181, a memory 183, and a communication interface 182.
- Communication interface 182 is used to communicate with external devices.
- the number of processors in the wireless network node 18 can be one or more.
- processor 181, memory 183, and communication interface 182 may be connected by a bus or other means.
- a wireless network node can be used to perform the method illustrated in FIG. For the meaning and examples of the terms involved in the embodiment, reference may be made to the embodiment corresponding to FIG. 5. I will not repeat them here.
- 183 memory stores program code.
- the 181 processor is configured to call the program code stored in the memory 183 for performing the following operations:
- the bearer type is SRB
- the bearer type is DRB
- the performing, by the processor, the function of performing the PHY layer on the uplink data packet and the function of the upper layer of the PHY layer includes:
- the processor is further configured to:
- the processor is further configured to:
- the received connection setup complete message is sent to the first wireless network node.
- the processor is further configured to:
- the target wireless network access node After receiving the handover complete message, the target wireless network access node performs security protection on the signaling data according to the SRB security information.
- the determining, by the processor, that the user equipment meets the handover condition, determining that the target wireless network node to be switched includes:
- a seventh embodiment of the present invention further provides a wireless network node.
- the wireless network node includes a processor 191, a memory 193, and a communication interface 192.
- the communication interface 192 is for communicating with an external device.
- the number of processors in the wireless network node 19 may be one or more.
- the processor 191, the memory 193, and the communication interface may be connected by a bus or other means.
- a wireless network node can be used to perform the method illustrated in FIG. For the meanings and examples of the terms involved in the embodiment, reference may be made to the corresponding embodiment of FIG. 8. I will not repeat them here.
- 193 memory stores program code.
- the processor 181 is configured to call the program code stored in the memory 183 for performing the following operations:
- the uplink data packet carries first indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the function of the PDCP layer is performed on the uplink data packet.
- the performing, by the processor, the function of completing the PDCP layer on the uplink data packet includes:
- the bearer type of the uplink data packet is the DRB, perform the function of the PDCP layer on the second data packet according to the DRB security information, and send the processed uplink data packet to the core network;
- the bearer type of the uplink data packet is SRB
- the function of the PDCP layer and the function of the RRC layer are performed on the second data packet according to the SRB security information.
- the processor is further configured to:
- the core network Receiving, by the core network, a downlink data packet, where the downlink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the first wireless network node performs the functions of the RRC layer and the function of the PDCP layer on the data packet, and sends the processed downlink data packet to the second wireless network node, so that the second wireless network node Obtaining, according to the second indication information, a user equipment, a bearer type, and a bearer of the downlink data packet.
- the processor is further configured to:
- the handover The command message is used to instruct the user equipment to complete the handover operation.
- the processor is further configured to:
- a handover indication message that carries the identifier of the target wireless network node, where the handover indication message is used to instruct the wireless network node to acquire UE context information of the user equipment, and The handover request message of the UE context information;
- the target wireless network node After receiving the handover response message returned by the target wireless network node, sending the handover response message to the second wireless network node, so that the wireless network node sends a handover to the user equipment according to the handover response message. And a command message, where the handover command message is used to instruct the user equipment to complete a handover operation.
- an eighth embodiment of the present invention further provides a wireless network node.
- the wireless network node 20 includes a processor 201, a memory 203, and a communication interface 202.
- the communication interface 202 is for communicating with an external device.
- the number of processors in the wireless network node 20 may be one or more.
- processor 201, memory 203, and communication interface 202 may be connected by a bus or other means.
- a wireless network node can be used to perform the method illustrated in FIG. turn off For the meanings and examples of the terms involved in this embodiment, reference may be made to the corresponding embodiment of FIG. I will not repeat them here.
- the program code is stored in the memory 203.
- the processor 201 is configured to call program code stored in the memory 202 for performing the following operations:
- the first wireless network node Receiving, by the first wireless network node, a downlink data packet, where the downlink data packet carries first indication information that identifies identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- the functions of the following layers of the PDCP layer are performed on the downlink data packet.
- the processor is further configured to:
- the uplink data packet carries second indication information indicating identity information of the user equipment, type information of the bearer, and identity information of the bearer;
- Performing a function of a layer of the PDCP layer on the uplink data packet, and transmitting the processed uplink data packet to the first wireless network node, so that the first wireless network node performs processing on the processed uplink data packet The function of the PDCP layer.
- the processor is further configured to:
- the first wireless network node Forwarding the measurement report sent by the user equipment to the first wireless network node, so that the first wireless network node, according to the measurement report, whether the user equipment meets a handover condition, the first Determining, by the wireless network node, a target wireless network node to be handed over, the first wireless network node returning a handover indication carrying the identity of the target wireless network node;
- the storage medium may be a magnetic disk, an optical disk, a read-only memory (ROM), or a random access memory (RAM).
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Abstract
本发明实施例公开了一种数据传输方法,包括:第一无线网络节点获知下行数据包的承载类型;在所述承载类型为信令无线承载SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行分组数据汇聚协议PDCP层的功能;或者在所述承载类型为数据无线承载DRB的情况下,所述第一无线网络节点对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。相应的,本发明实施例还公开了一种无线网络节点,能降低传输带宽和时延的要求。
Description
本发明涉及通信领域,尤其涉及一种数据传输方法、无线网络节点和通信系统。
随着业务的指数性增长,移动网络朝着5G移动网络演进。5G网络中需要提供更大带宽,更高的频谱效率等支持业务的爆炸式增长。使用超密集,低功率的小站网络可以有效地提供更高的数据量。但随着密集的网络部署,小区间干扰将增加,干扰场景更复杂。为了解决上述问题,一种集中式处理方案C-RAN被提出,能有效解决干扰问题和小站间的负载均衡,从而有效地增强系统容量。C-RAN系统由RRU(Remote Radio Unit,远端射频单元,简称RRU)和BBU池组成,BBU池中包括多个BBU(Base band Unit,基带单元,简称BBU)RRU和BBU池间通过CPRI(Common Public Radio Interface,通用公共无线电接口,简称CPRI)进行连接。
目前的C-RAN方案可以有效提高系统容量,但时RRU和BBU池之间需要非常理想的传输网,即CPRI需要理想的带宽和时延,例如支持8天线的20MHZ带宽小区,基带为20MHz带宽时,基带采样速率为30.72M,采样位宽15bit,则天线的线速率为30.72*15*2(IQ)*16/15(15bit数据,1bit控制位)=983.04M,经过8/10B编码后在CPIR上传输的速率为983.04M*10/8=1228.8M。也就是说,不采用MIMO(Multiple-Input Multiple-Output,多输入多输出,简称MIMO)的情况下,单天线单扇区就需要1228.8M的CPRI的传输速率;如果8天线,就需要再乘8,就达到10Gbit/s的传输速率。这要高的传输速率在RRU和BBU池之间很难实实现,因此目前急需一种既能降低传输带宽和时延要求的解决方案。
发明内容
本发明实施例所要解决的技术问题在于,提供一种数据传输方法、无线网
络节点和通信系统,可解决现有技术中传输带宽和时延要求高的问题。
为了解决上述技术问题,本发明实施例第一方面提供了一种数据传输方法,包括:
第一无线网络节点获知下行数据包的承载类型;
在所述承载类型为SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行PDCP层的功能;
在所述承载类型为DRB的情况下,所述第一无线网络节点对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
结合第一方面,在第一种可能的实现方式中,还包括:
所述第一无线网络节点接收所述第二无线网络节点发送的上行数据包;其中,所述第二无线网络节点对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,所述上行数据包的承载类型为DRB;
所述第一无线网络节点对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
结合第一方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
所述第一无线网络节点从所述核心网获取DRB安全信息和SRB安全信息,所述第一无线网络节点存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;
其中,所述第一无线网络节点对所述下行数据包执行PDCP层的功能包括:
所述第一无线网络节点根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
结合第一方面的第二种可能的实现方式,在第三种可能的实现方式中,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、完整性校验算法、加密算法、解密算法和安全密钥中的一种或多种。
结合第一方面,在第四种可能的实现方式中,所述第一无线网络节点获知下行数据包的承载类型之前,还包括:
所述第一无线网络节点接收所述第二无线网络节点发送的用户设备标识和连接请求;
在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,所述第一无线网络节点向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
结合第一方面至第四种可能的实现方式中的任意一种,在第五种可能的实现方式中,还包括:
在所述UE满足切换条件的情况下,所述第一无线网络节点从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;
所述第一无线网络节点从所述第二无线网络节点获取业务数据的传输状态参数;
在所述UE完成切换操作后,所述第一无线网络节点根据所述传输状态参数经由所述目标无线接网络节点与所述UE传输业务数据。
结合第一方面的第五种可能的实现方式,在第六种可能的实现方式中,所述第一无线网络节点从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点包括:
所述第一无线网络节点获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:RSRP、RSSI和RSRQ中的一种或多种。
本发明实施例第二方面提供一种无线网络节点,包括:
识别模块,用于获知下行数据包的承载类型;
第一发送模块,用于在所述承载类型为SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行PDCP层的功能;
第一处理模块,用于在所述承载类型为DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节
点。
结合第二方面,在第一种可能的实现方式中,还包括:
接收模块,用于接收所述第二无线网络节点发送的上行数据包;其中,所述上行数据包在所述第二无线网络节点执行PHY层的功能、MAC层的功能和RLC层的功能,所述上行数据包的承载类型为DRB;
第二处理模块,用于对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
结合第二方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
安全信息获取模块,用于从所述核心网获取DRB安全信息和SRB安全信息,所述第一无线网络节点存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;
其中,所述第一处理模块用于根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
结合第二方面的第二种可能的实现方式,在第三种可能的实现方式中,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、完整性校验算法、加密算法、解密算法和安全密钥中的一种或多种。
结合第二方面,在第四种可能的实现方式中,还包括:
SRB建立模块,用于接收所述第二无线网络节点发送的用户设备标识和连接请求;在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
结合第二方面至第四种可能的实现方式中的任意一种,在第五种可能的实现方式中,还包括:
切换模块,用于在所述UE满足切换条件的情况下,从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;从所述第二无线网络节点获取业务数据的传输状态参数;在所述UE完成切换操作后,根据所述传输
状态参数经由所述目标无线接网络节点与所述UE传输业务数据。
结合第二方面的第五种可能的实现方式,在第六种可能的实现方式中,所述切换模块用于获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:RSRP、RSSI和RSRQ中的一种或多种。
本发明实施例第三方面提供了一种无线网络节点,包括存储器和处理器,其特征在于,所述存储器保存有实现第一方面任意一种数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如第一方面任意一项所述的数据传输方法。
本发明实施例第四方面提供了一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:
获知下行数据包的承载类型;
在所述承载类型为信令无线承载SRB的情况下,将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行分组数据汇聚协议PDCP层的功能;或者
在所述承载类型为数据无线承载DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
本发明实施例第五方面提供了一种数据传输方法,包括:
第二无线网络节点获知用户设备发送的上行数据包的承载类型;
在所述承载类型为SRB的情况下,所述第二无线网络节点对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;
在所述承载类型为DRB的情况下,所述第二无线网络节点对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
结合第五方面,在第一种可能的实现方式中,所述第二无线网络节点对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能包括:
所述第二无线网络节点接收所述第一无线网络节点发送的SRB安全信息,
根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
结合第五方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
所述第五无线网络节点接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;
所述第二无线网络节点对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
结合第五方面,在第三种可能的实现方式中,还包括:
所述第二无线网络节点将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;
所述第二无线网络节点接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;
所述第二无线网络节点根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向所述第二无线网络节点返回连接建立完成消息;
所述第二无线网络节点将接收到的连接建立完成消息发送至所述第一无线网络节点。
结合第五方面的第一种可能的实现方式,在第四种可能的实现方式中,还包括:
所述第二无线网络节点在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;
所述第二无线网络节点向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向所述第二无线网络节点返回切换命令消息;
所述第二无线网络节点向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
结合第五方面的第四种可能的实现方式,在第五种可能的实现方式中,所述第二无线网络节点检测到所述用户设备满足切换条件时,确定待切换的目标无线网络节点包括:
所述第二无线网络节点在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或
所述第二无线网络节点在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备满足切换条件;或
所述第二无线网络节点在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足切换条件;
所述第二无线网络节点接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
本发明实施例第六方面一种无线网络节点,包括:
识别模块,用于获知用户设备发送的上行数据包的承载类型;
第一处理模块,用于在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;
第一发送模块,用于在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
结合第六方面,在第一种可能的实现方式中,所述第一处理模块用于接收所述第一无线网络节点发送的SRB安全信息,根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
结合第六方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
接收模块,用于接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;
第二处理模块,用于对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
结合第六方面,在第四种可能的实现方式中,还包括:
SRB建立模块,用于将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向所述第二无线网络节点返回连接建立完成消息;将接收到的连接建立完成消息发送至所述第一无线网络节点。
结合第六方面的第一种可能的实现方式,在第五种可能的实现方式中,还包括:
切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向所述第二无线网络节点返回切换命令消息;向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
结合第六方面的第五种可能的实现方式,在第六种可能的实现方式中,所述切换模块用于:
在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或
在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备满足切换条件;或
在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足切换条件;
接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
本发明实施例第七方面提供一种无线网络节点,包括存储器和处理器,其特征在于,所述存储器保存有实现如第五方面任意一项所述的数据传输方法的
指令,所述处理器调取并执行所述存储器中的指令,实现如第五方面任意一项所述的数据传输方法。
本发明实施例第八方面提供一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:
获知用户设备发送的上行数据包的承载类型;
在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;或
在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
本发明实施例第九方面提供了一种数据的传输方法,包括:
第一无线网络节点接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
所述第一无线网络节点根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;
所述第一无线网络节点对所述上行数据包执行PDCP层的功能。
结合第九方面,在第一种可能的实现方式中,所述第一无线网络节点对所述上行数据包完成PDCP层的功能包括:
所述第一无线网络节点获知所述上行数据包的承载类型;
在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;
在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
结合第九方面的第一种可能的实现方式,在第二种可能的实现方式中,还包括:
所述第一无线网络节点接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的
第二指示信息;
所述第一无线网节点对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
结合第九方面至第二种可能的实现方式中的任意一种,在第三种可能的实现方式中,还包括:
在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;
所述第一无线网络节点向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向所述第一无线网络节点返回切换响应消息;
所述第一无线网络节点接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
结合第九方面至第二种可能的实现方式中的任意一种,在第四种可能的实现方式中,还包括:
在所述UE满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点;
所述第一无线网络节点向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息;
所述第一无线网络节点根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向所述第一无线网络节点返回切换响应消息;
所述第一无线网络节点接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消
息用于指示所述用户设备完成切换操作。
本发明实施例第十方面提供了一种无线网络节点,包括:
第一接收模块,用于接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
识别模块,用于根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;
第一处理模块,用于对所述上行数据包执行PDCP层的功能。
结合第十方面,在第一种可能的实现方式中,所述第一处理模块用于获知所述上行数据包的承载类型;
在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;
在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
结合第十方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
第二接收模块,用于接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
第二处理模块,用于对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
结合第十方面至第二种可能的实现方式中的任意一种,在第三种可能的实现方式中,还包括:
第一切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;
向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向所述第一无线网络节点返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
结合第十方面至第二种可能的实现方式中的任意一种,在第四种可能的实现方式中,还包括:
第二切换模块,用于在所述UE满足切换条件的情况下,确定待切换的目标无线网络节点;
向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息;
根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向所述第一无线网络节点返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
本发明实施例第十一方面提供了一种无线网络节点,包括存储器和处理器,其特征在于,所述存储器保存有实现如第九方面任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如第九方面任意一项所述的数据传输方法。
本发明实施例第十二方面提供了一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:
接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;
对所述上行数据包执行PDCP层的功能。
本发明实施例第十三方面提供一种数据传输方法,包括:
第二无线网络节点接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
所述第二无线网络节点根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载;
所述第二无线网络节点对所述下行数据包执行PDCP层的以下层的功能。
结合第十三方面,在第一种可能的实现方式中,还包括:
所述第二无线网络节点接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
所述第二无线网络节点对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
结合第十三方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
所述第二无线网络节点将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向所述第二无线网络节点返回携带所述目标无线网络节点的身份标识的切换指示;
所述第二无线网络节点接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
本发明实施例第十四方面提供一种无线网络节点,包括:
第一接收模块,用于接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
识别模块,用于根据所述第一指示信息获知所述下行数据包对应的用户设
备、承载类型和承载;
第一处理模块,用于对所述下行数据包执行PDCP层的以下层的功能。
结合第八方面,在第一种可能的实现方式中,还包括:
第二接收模块,用于接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
第二处理模块,用于对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
结合第十四方面或第一种可能的实现方式,在第二种可能的实现方式中,还包括:
切换模块,用于将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向所述第二无线网络节点返回携带所述目标无线网络节点的身份标识的切换指示;
接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
本发明实施例第十五方面一种无线网络节点,其特征在于,包括存储器和处理器,其特征在于,所述存储器保存有实现第三方面任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如第三方面任意任意一项所述的数据传输方法。
本发明实施例第十六方面一种存储介质,用于控制计算机设备执行手势控制方法,所述方法包括以下步骤:
接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和
承载;
对所述下行数据包执行PDCP层的以下层的功能。
实施本发明,具有如下有益效果:
通过对第一无线网络节点和第二无线网络节点中各个层重新进行划分:第一无线网络节点负责对DRB中承载的业务数据进行安全保护,无线网络节点负责对SRB中承载的信令数据进行安全保护;或第一无线网络节点负责RRC层和PDCP层处理,第二无线网络节点负责PDCP以下层的处理,采用这种形式结构,与现有技术中的CPRI接口相比,两个网络节点之间传输的数量减少,从而能降低减少二者之间传输带宽和时延的需求。
为了更清楚地说明本发明实施例或现有技术中的技术方案,下面将对实施例中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本发明的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。
图1为本发明实施例提供的一种网络结构图;
图2是本发明实施例提供的一种基站的结构示意图;
图3是本发明实施例提供的一种基站的另一结构示意图;
图4是本发明第一实施例提供的一种数据传输方法的流程示意图;
图5是本发明第二实施例提供的一种数据传输方法的流程示意图;
图6是本发明第三实施例提供的一种数据传输方法的流程示意图;
图7是本发明第一实施例提供的一种UE切换方法的流程示意图;
图8是本发明第四实施例提供的一种数据传输方法的流程示意图;
图9是本发明第五实施例提供的一种数据传输方法的流程示意图;
图10是本发明第六实施例提供的一种数据传输方法的流程示意图;
图11是本发明第二实施例提供一种UE切换方法的流程示意图;
图12是本发明第三实施例提供的一种UE切换方法的流程示意图;
图13是本发明第一实施例提供的一种无线网络节点的结构示意图;
图14是本发明第二实施例提供的一种无线网络节点的结构示意图;
图15是本发明第三实施例提供的一种无线网络节点的结构示意图;
图16是本发明第四实施例提供的一种无线网络节点的结构示意图;
图17是本发明第五实施例提供的一种无线网络节点的结构示意图;
图18是本发明第六实施例提供的一种无线网络节点的结构示意图;
图19是本发明第七实施例提供的一种无线网络节点的结构示意图;
图20是本发明第八实施例提供的一种无线网络节点的结构示意图。
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例,而不是全部的实施例。基于本发明中的实施例,本领域普通技术人员在没有作出创造性劳动前提下所获得的所有其他实施例,都属于本发明保护的范围。
参见图1,为本发明实施例以LTE(Long Term Evolution,长期演进,简称LTE)为基础的网络结构图,接入网包括RC和RAP集群,RC(Radio Access Network Controller,无线接入网控制器,简称RC)管理一个RAP(Radio Access Point,无线接入站点,简称RAP)集群,RAP集群中包含至少一个RAP,RC和RAP集群之间通过TN(Transportation Network,传输网,简称TN)连接,UE和RAP集群中的至少一个RAP有连接;RC与核心网之间通过S1接口连接,核心网包括移动管理实体MME、服务网关SGW和数据网关PGW,核心网控制面和用户面分离,其中在控制面MME与RC之间通过S1-MME接口连接,在用户面SGW与RC之间通过S1-U接口连接。RC和管辖的RAP集群相当于LTE网络架构中的eNodeB(evolved Node B,演进型基站),RC和eNodeB之间通过X2接口进行连接,eNodeB和核心网之间通过S1接口进行连接,UE通过RAP集群中的一个RAP接入到核心网。
除上述的LTE通信制式,本发明还可以应用于GSM(Global System of Mobile communication,全球移动通讯)或CDMA(Code Division Multiple Access,码分多址)中的,也可以是WCDMA(Wideband Code Division Multiple Access,宽带码分多址),或者未来5G网络制式,或者是无线局域网(Wireless Local Area Networks,WLAN)、全球微波互联接入(Worldwide Interoperability for
Microwave Access,WiMAX)、蓝牙和红外线等其他通信制式。
参见图2,为本发明实施例提供的一种基站的结构示意图,在本发明实施例中,演进基站包括第一无线网络节点和无线网络节点,第一无线网络节点包括第一RRC(Radio Resource Control,无线资源控制,简称RRC)子层和第一PDCP(Packet Data Convergence Protocol,分组汇聚协议,简称PDCP)子层对应的功能,无线网络节点包括第二RRC子层、第二PDCP子层、RLC(Radio Link Control,无线链路控制,简称RLC)层、MAC(Media Access Control,介质访问控制,简称MAC)层和PHY(Physical,物理的,简称PHY)层对应的功能,其中,第一RRC子层和第二RRC子成共同组成RRC层,第一RRC子层的功能为用于全局RRC配置管理,第二RRC子层的功能为用于SRB(Signalling Radio Bearers,信令无线承载,简称SRB)的生成、发送、接收和本地RRC配置管理,第一PDCP子层的功能为用于DRB(Data Radio Bearers,数据无线承载,简称DRB)的处理,第二PDCP子层的功能为用于SRB的处理。本发明实施例的基站结构,与现有RRH(Remote Radio Head,射频拉远头,简称RRH)拉远方式中的拉远接口相比,RC和RAP之间传输的接口所传输的数据量相对较少,有利于减轻RC(Radio access network Controller,无线接入网控制器,简称RC)和RAP(Radio Access Point,无线接入站点,简称RAP)之间交互的数据量,从而降低传输带宽和时延的要求。
参见图3,为本发明实施例提供的一种基站的结构示意图,在本发明实施例中,演进基站包括第一无线网络节点和第二无线网络节点,第一无线网络节点包括RRC层和PDCP层,用于完成RRC层和PDCP层对应的功能;无线网络节点包括RLC层、MAC层和PHY层,用于完成RLC层、MAC层和PHY层对应的功能。其中,PDCP层对应的功能包括:头压缩、安全和重排序;RLC层对应的功能包含分割、级联、自动重传请求(ARQ,Automatic Repeat Request);MAC层的对应的功能包括:调度、逻辑信道优先级处理、HARQ(Hybrid Automatic Repeat Request,混合自动重传)等;PHY层对应的功能包括:调制解调、编码、多天线映射。本发明实施例中的基站的结构,与现有RRH拉远方式中的拉远接口相比,RC和RAP之间传输的接口所传输的数据量相对较少,有利于减轻RC和RAP之间交互的数据量,从而降低传输带宽和时延的要求。
参见图4,为本发明第一实施例提供的一种数据传输方法的流程示意图,在本发明实施例中利用图2的网络架构实现本发明实施例所述的一种数据保护方法,所述方法包括:
S401、第一无线网络节点获知下行数据包的承载类型。
具体的,第一无线网络节点接收核心网下发的下行数据包,下行数据包的承载类型分为SRB和DRB,即下行数据包分为业务数据和信令数据,第一无线网络节点可以根据下行数据包中携带的承载类型标识来获知下行数据包的承载类型。
S402、在所述承载类型为SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包进行PDCP层处理。
具体的,如果下行数据包的承载类型为SRB,即下行数据包为信令数据,第一无线网络节点不处理信令数据,第一无线网络节点将下行数据包转发给第二无线网络节点,由第二无线网络节点对下行数据包的RRC层获知下行数据包为信令数据,然后第二无线网络节点的PDCP层、RLC层、MAC层和PHY层对分别对下行数据包进行处理,第二无线网络节点将处理后的下行数据包发送给用户设备。
S403、在所述承载类型为DRB的情况下,所述第一无线网络节点对所述下行数据包进行PDCP层处理,并将处理后的下行数据包发送给所述第二无线网络节点。
具体的,如果下行数据包的承载类型为DRB,即下行数据包为业务数据,第一无线网络节点对下行数据包进行PDCP层处理,PDCP层处理包括:头压缩、安全和重排序中的一种或多种,第一无线网络节点将PDCP层处理后的下行数据包发送给第二无线网络节点,由第二无线网络节点对该下行数据包继续进行RLC层处理、MAC层处理和PHY层处理,第二无线网络节点完成上述处理环节后,将处理后的下行数据包发送给用户设备。
可选的,所述第一无线网络节点接收所述第二无线网络节点发送的上行数据包;其中,所述上行数据包在所述第二无线网络节点完成PHY层处理、MAC层处理和RLC层处理,且所述上行数据包的承载类型为DRB;
所述第一无线网络节点将所述上行数据包进行PDCP层处理后发送给所述核心网。
具体的,第二无线网络节点负责信令数据的处理,第一无线网络节点负责业务数据的处理,第二无线网络节点接收到用户设备发送的上行数据包,将上行数据包经过PHY层处理、MAC层处理、RLC层处理,获知上行数据包的承载类型为DRB后,将处理后的上行数据包发送给第一无线网络节点继续进行PDCP层处理,第一无线网络节点对上行数据包进行PDCP层处理包括:根据获取的DRB安全信息对上行数据包进行安全处理。
可选的,还包括:所述第一无线网络节点从所述核心网获取DRB安全信息和SRB安全信息;
所述第一无线网络节点将所述SRB安全信息发送给所述第二无线网络节点;所述第一无线网络节点对所述下行数据包进行PDCP层处理包括:
所述第一无线网络节点根据所述DRB安全信息对所述下行数据包进行PDCP层处理。
具体的,第一无线网络节点利用DRB安全信息对业务数据进行PDCP层处理,即承载类型为DRB的数据包进行安全保护,第一无线网络节点将SRB安全信息发送给第二无线网络节点,第二无线网络节点对信令数据进行PDCP层处理。
其中,SRB安全信息和DRB安全信息包括如下至少一种:完整性保护算法,完整性校验算法,加密算法,解密算法及安全密钥。完整性保护算法用于在消息中增加冗余信息以保护消息完整性,完整性校验算法用于根据消息中的冗余信息判断消息是否被更改,加密算法用于对消息进行加密生成密文,加密时使用加密密钥;解密算法用于对密文进行解密生成明文,解密时使用解密密钥;完整性保护算法和完整性校验算法可为同一算法,加密算法和解密算法也可为同一算法;完整性保护时所用的密钥、完整性校验时所用的密钥、加密时所用的加密密钥,和解密时所用的解密密钥可以为同一安全密钥,也可以是同一安全密钥基础上衍生的不同的安全密钥。
可以理解的是,SRB安全信息和DRB安全信息可以从核心网中获取,也可以从其他网络节点中获取,本发明不作限制。
实施本发明的实施例,第一无线网络节点负责对DRB中承载的业务数据进行安全保护,无线网络节点负责对SRB中承载的信令数据进行安全保护,二者进行分工,能减少第一无线网络节点和无线网络节点之间的数据传输量,减少二者之间传输带宽的需求,并能快速完成底层配置和最大限度地保证业务连续性。
参见图5,为本发明第二实施例提供的一种数据传输方法的流程示意图,在本发明实施例中,所述方法包括:
S501、第二无线网络节点获知UE发送的上行数据包的承载类型。
具体的,UE向第二无线网络节点发送上行数据包,上行数据包的承载类型分为SRB或DRB,即上行数据包分为业务数据或信令数据,第二无线网络节点可以根据上行数据包中携带的承载类型标识获知上行数据包的承载类型。
S502、在所述承载类型为SRB的情况下,所述第二无线网络节点对所述上行数据包完成PHY层处理、MAC层处理、RLC层处理、PDCP层处理和RRC层处理。
具体的,如果上行数据包的承载类型为SRB,即上行数据包为信令数据,第二无线网络节点对上行数据包完成成PHY层处理、MAC层处理、RLC层处理、PDCP层处理和RRC层处理,处理后生成RRC信令。其中,第二无线网络节点对上行数据包进行PDCP层处理包括:利用SRB安全信息对上行数据包进行安全保护。
S503、在所述承载类型为DRB的情况下,所述第二无线网络节点将所述上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述上行数据包完成PDCP层处理。
具体的,如果上行数据包的承载类型为SRB,即上行数据包为业务数据,第二无线网络节点不对业务数据进行PDCP层处理,第二无线网络节点对上行数据包完成PHY层处理、MAC层处理和RLC层处理后,将处理后的上行数据包发送给第一无线网络节点,由第一无线网络节点继续对该上行数据包进行PDCP层的处理,其中,PDCP层处理包括:利用DRB安全信息对上行数据包进行安全保护。
其中,SRB安全信息和DRB安全信息可以由第一无线网络节点可以从核
心网获取,SRB安全信息和DRB安全信息包括如下至少一种:完整性保护算法,完整性校验算法,加密算法,解密算法及安全密钥,第一无线网络节点利用DRB安全信息对业务数据进行安全保护,同时,第一无线网络节点将SRB安全信息发送给第二无线网络节点,第二无线网络节点根据SRB安全信息对信令数据进行安全保护。
实施本发明的实施例,第一无线网络节点负责对DRB中承载的业务数据进行安全保护,无线网络节点负责对SRB中承载的信令数据进行安全保护,二者进行分工,能减少第一无线网络节点和无线网络节点之间的数据传输量,减少二者之间传输带宽的需求,并能快速完成底层配置和最大限度地保证业务连续性。
下面以RC为第一无线网络节点,UE接入的RAP为无线网络节点为例,对本发明实施例的数据保护方法进行详细的说明。
参见图6,为本发明实施例第三实施例提供的一种数据传输方法的流程示意图,利用图2中的架构来实现本发明实施例所述的数据传输方法,本发明实施例中的RC为第一无线网络节点,RAP为第二无线网络节点,所述方法包括:
S601、UE向RAP发送RRC连接建立请求消息,RRC连接请求中携带UE的UE标识。
具体的,UE向RAP发送RRC连接建立请求消息,RRC连接建立请求消息用于UE与RAP建立RRC连接。RRC连接请求通过默认SRB(SRB0)发送,RRC连接请求用于UE和网络建立RRC连接,并建立新的SRB,例如,SRB1、SRB2和SRB3。UE标识可以是S-TMSI或C-RNTI等,用于标识UE的唯一身份。
S602、RAP将RRC连接请求并UE标识发送给RC。
具体的,RC和RAP是一对多的对应关系,RAP唯一对应一个RC,RAP根据对应关系确定所属的RC,将RRC连接请求并UE标识发送给RC,其中UE标识可包含在RRC连接请求中。
S603、RC对UE标识对应的用户设备进行准入控制。
具体的,RC判断UE是否具有接入RAP的权限,若UE具有接入RAP的权限,执行S604。RC判断UE是否具有接入RAP的权限的方法可以是:
RC根据RAP和周围RAP的负荷状态参数、干扰状态参数、UE的业务类型信息和UE的签约信息中的一种或多种来判断UE是否具有接入RAP的权限。例如,RAP的负荷过高,UE的签约信息中UE的接入等级低于预设接入等级,RC拒绝UE接入RAP,反之,RC允许UE接入RAP。
S604、RC向RAP返回准入指示,并带UE标识,准入指示消息用于指示允许UE接入RAP。
S605、RAP向UE发送RRC连接建立消息。
具体的,RAP接收到RC发送的准入指示后生成RRC连接建立消息,将生成的RRC连接建立消息发送给UE标识对应的用户设备。
S606、UE与RAP建立RRC连接,RRC连接建立完成后,UE向RAP返回RRC连接建立完成消息。
具体的,UE成功建立RRC连接后,表示新的SRB已成功建立。UE向RAP返回RRC连接建立完成消息在新的SRB中传输。
S607、UE向RAP返回RRC连接建立完成消息。RAP接收到RRC连接建立完成消息得知新的SRB建立成功。
S608、RAP向RC返回RRC连接建立完成指示。RC接收到RRC连接建立完成指示得到新的SRB建立成功。
需要说明的是,上述S601-S607的流程由位于图2的RAP上的第二RRC子层和位于RC上的第一RRC子层完成。
S609、RC和核心网之间触发UE初始上下文建立流程。
具体的,接收到RAP发送的RRC连接建立完成指示后,RC触发完成UE初始上下文建立流程,例如,RC发送UE初始上下文建立请求消息,UE初始化上下文建立流程完成后,核心网向RC发送UE上下文信息。
S610、发送携带DRB安全信息和SRB安全信息和/或DRB的QoS参数的UE上下文信息。
具体的,RC将DRB安全信息、SRB安全信息和DRB的QoS参数发送至RAP,RAP根据上述信息的一种或多种生成RRC连接重配置消息,用于完成对UE的DRB建立、SRB的重配置以及安全激活。RAP保存SRB安全信息和DRB的QoS参数。
S611、根据DRB安全信息对DRB中承载的业务数据进行安全保护,根据QoS参数对DRB中承载的业务数据进行服务质量控制。
具体的,UE上下文信息包括:DRB安全信息、SRB安全信息和DRB的QoS参数,DRB安全信息和SRB安全信息包括安全密钥、加密算法、解密算法、完整性保护算法和完整性校验算法,其中DRB安全信息和SRB安全信息可相同,即使用相同的安全信息用于DRB和SRB进行安全保护。QoS参数表示DRB中传输的业务数据的服务质量需求,例如,QoS参数包括最大传输速率、最小保证速率或传输时延。QoS参数可由核心网下发给RC,RC根据RAP和周围RAP的负荷状态参数对QoS参数进行调整生成新的QoS参数。其中,RC还触发对UE的DRB的建立、UE的SRB的重配置和安全配置。
业务数据的安全保护过程以数据传输的下行方向为例:RC接收到核心网下发的业务数据后,RC完成对业务数据的PDCP功能后生成PDCP PDU,对PDCP PDU进行头压缩,根据加密算法和加密密钥对PDCP PDU加密,为PDCP PDU增加序列号,RC将PDCP PDU下发给RAP,由RAP完成对PDCP PDU的RLC层、MAC层和PHY层对应的功能,例如:RAP完成对PDCP PDU的分段、调度、调制编码,并根据生成的QoS参数对DRB中承载的业务数据进行服务质量控制。
S612、RC将SRB安全信息发送至RAP。
S613、RAP根据SRB安全信息对SRB中承载的信令数据进行安全保护。
具体的,在安全保护功能被激活后,RAP对SRB中承载的信令数据进行安全保护,安全保护如加密、解密、完整性保护和完整性校验,信令数据如RRC信令。
参见图7,为本发明第一实施例提供的一种UE切换方法的流程示意图,在本发明实施例中,所述方法包括:
S701、源RAP检测到UE满足切换条件时,执行S702。
具体的,在UE发生切换之前,UE接入到源RAP,源RAP判断UE是否满足切换条件,判断的方法可以是:源RAP根据接收的UE的信号载波电平判定,UE的信号载波电平低于门限电平,则确定UE满足切换条件;或源RAP根据接收的UE的信号载干比判定,当UE的信号载干比低于给定值时,则确
定UE满足切换条件;或源RAP根据到UE的距离判定,当源RAP与UE的距离大于给定值时,确定UE满足切换条件。源RAP在判断切换条件满足时,需要获取UE待切换的目标RAP,目标RAP的确定可由有源RAP来执行,也可以由RC来执行,本发明不作限制。
S702、源RAP向RC获取待切换的目标RAP。
具体的,目标RAP的选择由RC来执行,源RAP向对应的RC发送获取目标RAP的请求,该请求用于请求RC从自身的RAP集合中选择除源RAP以外的目标RAP。
S703、RC确定待切换的目标RAP。
具体的,RC管理RAP集合,RAP集合中包括RAP和至少一个其他RAP,RC可获取RAP集合中各个RAP上报的与UE之间的链路状态参数,RC将链路状态参数最优的RAP作为待切换的目标RAP。链路状态参数包括RSSI、RSRP和RSRQ中的一种或多种。
S704、RC向RAP发送目标RAP的标识。
S705、源RAP获取SRB的SRB安全信息,并发送携带SRB安全信息的切换请求消息至目标RAP。
具体的,源RAP获取与UE之间的SRB的SRB安全信息,安全信息包括安全密钥、加密算法、解密算法、完整性保护算法和完整性校验算法中的一种或多种,源RAP根据目标RAP的标识确定目标RAP,向目标RAP发送携带SRB安全信息的切换请求消息。
S706、目标RAP准备切换资,切换资准备完成后,向源RAP返回切换命令消息。
具体的,切换资源包括频谱资源、硬件资源等,目标RAP接收并保存源RAP的SRB安全信息,以便于UE切换至目标RAP后,目标RAP使用该SRB安全信息对与UE之间的SRB进行安全保护,RC与UE之间的DRB的DRB安全信息保持不变,即UE切换至目标RAP后,RC继续使用原有的DRB安全信息对DRB上的业务数据做安全保护。
S707、目标RAP向源RAP发送切换命令消息。
其中,目标RAP在准备好切换资源置换,向源RAP发送切换命令消息,
以通知目标RAP自身的切换资源已准备好,UE可以进行切换操作了。
S708、源RAP向UE发送切换命令消息。
S709、UE执行切换操作。UE执行切换操作后,接入到目标RAP上。
S710、源RAP发送传输状态参数至RC。
具体的,传输状态参数可以是PDCP状态报告,分为上行传输状态参数和下行传输状态参数。对于下行方向,传输状态参数表示成功发送或未成功发送至UE的PDCP数据包的序列号,以成功发送的PDCP数据包的序列号为例,当前RAP成功向UE发送的PDCP数据包的序列号为3,则RC向目标RAP发送第4个PDCP数据包;对于上行方向,传输状态参数表示成功或未成功发送至RC的PDCP数据包的序列号,RC将上行传输状态参数发送给UE,以使UE根据序列号发送PDCP数据包至目标RAP,避免数据的重复传输。
S711、RC将传输状态参数发送至目标RAP。
参见图8,为本发明实施例第四提供的一种数据传输方法的流程示意图,通过图3的结构示意图来实现本发明实施例的数据传输方法,所述方法包括:
S801、第一无线网络节点接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示UE的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
具体的,第二无线网络节点接收UE发送的上行数据包,上行数据包中携带UE的身份信息、承载的类型信息和承载的身份信息,第二无线网络节点将上对上行数据包经过PHY层处理、MAC层处理和RLC层处理,将处理后的上行数据包发送给第一无线网络节点,处理后的上行数据包携带表示UE的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
S802、所述第一无线网络节点根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载。
具体的,第一无线网络节点根据上行数据包中的携带的第一指示信息获知上行数据包对应的用户设备、承载类型以及承载,承载类型分为SRB和DRB。其中,第一指示信息可以是GTP隧道标识,
S803、所述第一无线网络节点对所述上行数据包完成PDCP层处理。
具体的,第一无线网络节点将上行数据包进行PDCP层处理,PDCP层处
理包括头压缩、安全和重排序中的一种或多种。
参见图9,为本发明实施例第五实施例提供的一种数据保护方法的流程示意图,在本发明实施例中,所述方法包括:
S901、第二无线网络节点接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识UE的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
具体的,核心网向第一无线网络节点发送下行数据包,下行数据包中携带UE的身份信息、承载的类型信息和承载的身份信息,第一无线网络节点可通过RRC层获知上行数据包的承载的类型信息,第一无线网络节点对上行数据包进行PDCP层处理,将处理后的下行数据包发送给第二无线网络节点,处理后的下行数据包中携带UE的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
S902、所述第二无线网络节点根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载。
具体的,承载类型分为SRB和DRB,不同的UE对应不同的承载。
S903、所述第二无线网络节点对所述下行数据包完成RLC层处理、MAC层处理和PHY层处理。
具体的,第二无线网络节点对下行数据包完成RLC层处理、MAC层处理和PHY层处理,根据UE的身份信息,将处理后的下行数据包发送给对应的用户设备。
参见图10,为本发明第六实施例提供的一种数据传输方法的流程示意图,在本发明实施例中,RC为第一无线网络节点,RAP为第二无线网络节点,所述方法包括:
S1001、UE向RAP发送携带UE标识的RRC连接建立请求消息。
具体的,UE预先建立默认承载SRB0,UE通过SRB0发送RRC连接请求,RRC连接请求用于为UE建立新的SRB,例如,SRB1、SRB2或SRB3,UE标识用于唯一标识UE的身份,UE标识可以是S-TMSI或C-RNTI等。
S1002、RAP接收RRC连接建立请求消息,以及为待建立的SRB分配第一SRB标识。
具体的,RAP为待建立的SRB分配第一SRB标识,第一SRB标识用于RAP唯一标识待建立的SRB的身份(下行方向),例如,可以通过在待建立的SRB中传输的信令消息中添加GTP隧道标识作为待建立的SRB的第一SRB标识。RAP在下行方向可以通过获知第一SRB标识来确定待建立的SRB。RAP在本地保存第一SRB标识和UE标识的映射关系。
S1003、RAP向RC发送携带UE标识和第一SRB标识的RRC连接请求转发给RC。
具体的,RAP将第一SRB标识和UE标识添加到RRC连接请求中,然后将该RRC连接请求发送至RC,此时的RRC连接请求仍然通过默认承载SRB0发送至RC。
S1004、RC对UE进行准入控制,允许UE接入RAP后分配第二SRB标识,生成SRB配置信息。
具体的,RC从接收到的RRC连接请求中解析得到UE标识和第一SRB标识,对UE标识对应的用户设备执行准入控制,准入控制的方法可以是:RC根据RAP和周围RAP的负荷状态参数、干扰状态参数、UE的业务类型信息和UE的签约信息中的一种或多种来判断UE是否具有接入RAP的权限。例如,RAP的负荷过高,UE的签约信息中UE的接入等级低于预设接入等级,RC拒绝UE接入RAP,反之,RC允许UE接入RAP。RC确定UE具有接入RAP的权限后,为待建立的SRB分配第二SRB标识,第二SRB标识用于在RC唯一标识待建立的SRB的身份(上行方向),RC在本地保存第一SRB标识、第二SRB标识和UE标识的映射关系。同时,RC生成SRB配置信息,SRB配置信息包括第一SRB配置信息和第二SRB配置信息,其中,第一SRB配置信息用于对RAP的RLC层、MAC层和PHY层进行配置,第二SRB配置信息用于UE对RRC层、PDCP层、RLC层、MAC层和PHY层进行配置,配置完成后,UE建立新的SRB。例如,可以通过在SRB配置信息中携带不同的标识来区分第一SRB配置信息和第二SRB配置信息,第一SRB信息用于发送给RAP,第二SRB配置信息用于发送给UE。
S1005、RC向RAP发送携带第一SRB标识、第二SRB标识和SRB配置信息的RRC连接建立消息。
S1006、RAP根据第一SRB配置信息完成底层配置。
具体的,RAP从接收到的RRC连接建立消息中解析出第一SRB标识、第二SRB标识和SRB配置信息,RAP根据第一SRB标识获知UE的待建立的SRB,获知SRB配置信息中的第一SRB配置信息,根据第一SRB配置信息对RLC层、MAC层和PHY层进行配置。RAP获知SRB配置信息中的第二SRB配置信息,将第二SRB配置信息添加到RRC连接建立消息中。所述第一SRB配置信息或/和第二SRB配置信息中包含第三SRB标识,所述第三SRB标识用于获知UE和RAP间的信令数据。RAP保存第三SRB标识和第一SRB标识/第二SRB标识的关系。
S1007、RAP将携带第二SRB配置信息的RRC连接建立消息发送至UE。
具体的,UE根据第二SRB配置信息对自身的RRC层、PDCP层、RLC层、MAC层和PHY层进行配置,建立新的SRB(例如:SRB1),UE在成功建立SRB1后,向RAP返回RRC连接建立完成消息。此时RRC连接建立完成消息通过新的SRB1发送的,同时RRC连接建立完成消息中携带UE标识。
S1008、UE向RAP发送携带UE标识的RRC连接建立完成消息,用于通知RC新的SRB建立成功。
S1009、RAP向RC发送携带第二SRB标识的RRC连接建立完成消息。其中,第三SRB标识表示第二SRB配置信息的标识,RAP根据第三SRB标识和第二SRB标识之间的映射关系查询第二SRB标识,将第二SRB标识添加到RRC连接建立完成消息中,RC根据第二SRB标识获知UE的新的SRB。
S1010、RC与核心网之间触发初始上下文建立流程。
具体的,RC通过UE初始上下文建立流程从核心网获得上述建立的新的SRB的SRB安全信息、待建立的DRB的DRB安全信息和待建立的DRB的QoS参数。
S1011、RC获取DRB安全信息、SRB安全信息、DRB的QoS参数。
具体的,RC获取待建立的DRB的DRB安全信息、新的SRB的SRB安全信息和待建立的DRB的安全信息,同时,RC生成DRB配置信息,DRB配置信息分为两类,第一DRB配置信息在RAP上进行底层配置,第二DRB配置信息在UE上进行建立DRB的配置,第二DRB配置信息和第二DRB配置
信息可以通过不同的表示来区分。RC还待建立的DRB分配第一DRB标识,用于RC唯一获知UE的DRB的身份。
S1012、RC发送第一DRB配置信息和第一DRB标识。
S1013、RAP获知第一DRB配置信息,根据第一DRB配置信息对RLC层、MAC层和PHY层进行DRB配置,RAP完成DRB配置后,为DRB分配第二DRB标识,第二DRB标识用于RAP唯一获知UE的DRB的身份。RAP获知DRB配置信息中的第二DRB配置信息。第一DRB配置信息和\或第二DRB配置信息中包含第三DRB标识,所述第三DRB标识用于获知UE和RAP间的DRB。
S1014、RAP向RC发送携带第一DRB标识和第二DRB标识的DRB配置完成消息。
S1015、RC接收DRB配置完成消息后,生成RRC连接重配消息,RRC连接重配消息用于指示UE建立DRB。
S1016、RC向RAP发送携带第一SRB标识和第二DRB配置信息的RRC连接重配消息。
S1017、RAP根据第一SRB标识获知SRB所属的UE。
S1018、RAP向UE发送携带第二DRB配置信息的RRC连接重配消息。
S1019、UE根据第二DRB配置信息对DRB进行配置,建立DRB,成功建立DRB后,UE向RAP返回RRC连接重配完成消息,其中,RRC连接重配消息携带第二SRB配置消息的标识。
S1020、RAP向RC发送携带第二SRB标识的RRC连接重配完成消息。
S1021、RC根据SRB安全信息和DRB安全信息对创建的SRB和DRB进行安全保护。
S1022、RC向RAP发送经过安全保护的业务数据,业务数据中携带第一DRB标识和第二DRB标识,信令数据中携带第一SRB标识和第二SRB标识,在上行方向,RC根据业务数据中携带的第一DRB标识获知该业务消息属于UE,根据信令数据中携带的第二SRB标识获知该信令消息属于UE。
参见图11,为本发明第二实施例提供的一种UE切换方法的流程示意图,
在本发明实施例中,所述方法包括:
S1101、UE触发随机接入流程,UE与源RAP和RC之间建立随机接入信道。
S1102、源RAP将UE上下文信息发送至RC。UE上下文信息包括C-RNTI或无线资配置信息等。
S1103、RC保存UE上下文信息。
S1104、UE执行RRM测量。
S1105、UE将执行RRM测量后生成的测量报告发送给RAP。
S1106、源RAP将测量报告发送给RC。
S1107,RC根据测量报告检测UE是否满足切换条件,若满足,准备切换资,执行S1107,同时UE确定可以根据测量报告确定待切换的目标RAP。
S1108、RC向目标RAP发送携带UE上下文信息的切换请求消息。
S1109、目标RAP对UE进行准入控制,判断UE是否允许接入目标RAP,若UE允许接入目标RAP,执行S1110。
S1110、目标RAP向RC返回切换响应消息。
S1111、RC向源RAP发送切换命令消息。
S1112、执行切换操作,UE从源RAP上切换到目标RAP上,切换成功后,目标RAP利用UE上下文信息中的SRB安全信息对信令数据进行安全保护,以及利用DRB安全信息对业务数据进行安全保护。
参见图12,为本发明第三实施例提供的一种UE切换方法的流程示意图,在本发明实施例中,所述方法包括:
S1201、UE执行RRM测量。
S1202、UE将执行RRM生成的测量报告发送给RAP。
S1203、源RAP将测量报告转发给RC。
S1204、RC根据测量报告检测UE是否满足切换条件,若满足,执行S705,RC同时确定待切换的目标RAP。
S1205、RC向源RAP发送携带目标RAP的标识的切换指示。
S1206、源RAP向RC返回携带目标RAP的标识的切换要求消息。
S1207、RC向目标RAP发送携带UE上下文信息的切换请求消息。
S1208、目标RAP对UE执行准入控制,在允许UE接入后,准备切换资。
S1209、目标RAP向RC发送切换响应消息。
S1210、RC向源RAP发送切换命令消息。
S1211、执行切换操作。UE从源RAP切换到目标RAP上,切换成功后,目标RAP利用UE上下文信息中的SRB安全信息对信令数据进行安全保护,以及利用DRB安全信息对业务数据进行安全保护。
参见图13,为本发明第一实施例提供的一种无线网络节点的结构示意图,在本发明实施例中,所述无线网络节点包括:识别模块1301、第一发送模块1302和第一处理模块1303。
识别模块1301,用于获知下行数据包的承载类型。
第一发送模块1302,用于在所述承载类型为SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行PDCP层的功能。
第一处理模块1303,用于在所述承载类型为DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
可选的,本发明实施例的无线网络节点还包括:
接收模块,用于接收所述第二无线网络节点发送的上行数据包;其中,所述第二无线网络节点对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,所述上行数据包的承载类型为DRB;
第二处理模块,用于对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
可选的,本发明实施例的无线网络节点还包括:
安全信息获取模块,用于从所述核心网获取DRB安全信息和SRB安全信息,所述第一无线网络节点存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;
其中,所述第一处理模块用于根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
可选的,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、
完整性校验算法、加密算法、解密算法和安全密钥中的一种或多种。
可选的,本发明实施例的无线网络节点还包括:
SRB建立模块,用于接收所述第二无线网络节点发送的用户设备标识和连接请求;在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
可选的,本发明实施例的无线网络节点还包括:
切换模块,用于在所述UE满足切换条件的情况下,从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;从所述第二无线网络节点获取业务数据的传输状态参数;在所述UE完成切换操作后,根据所述传输状态参数经由所述目标无线接网络节点与所述UE传输业务数据。
可选的,所述切换模块用于获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:RSRP、RSSI和RSRQ中的一种或多种。
本发明实施例和方法实施例一基于同一构思,其带来的技术效果也相同,具体过程请参照方法实施例一的描述,此处不再赘述。
参见图14,为本发明第二实施例提供的一种无线网络节点,其特征在于,包括:识别模块1401、第一处理模块1402和第一发送模块1403。
识别模块,用于获知用户设备发送的上行数据包的承载类型;
第一处理模块,用于在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;
第一发送模块,用于在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
可选的,所述第一处理模块用于接收所述第一无线网络节点发送的SRB
安全信息,根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
可选的,本发明实施例的无线网络节点还包括:
接收模块,用于接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;
第二处理模块,用于对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
可选的,本发明实施例的无线网络节点还包括:
SRB建立模块,用于将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向所述第二无线网络节点返回连接建立完成消息;将接收到的连接建立完成消息发送至所述第一无线网络节点。
可选的,本发明实施例的无线网络节点还包括:
切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向所述第二无线网络节点返回切换命令消息;向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
可选的,所述切换模块用于:
在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或
在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备满足切换条件;或
在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足
切换条件;
接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
本发明实施例和方法实施例二基于同一构思,其带来的技术效果也相同,具体过程请参照方法实施例二的描述,此处不再赘述。
参见图15,为本发明第三实施例提供一种无线网络节点包括:第一接收模块1501、识别模块1502和第一处理模块1503。
第一接收模块1501,用于接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
识别模块1502,用于根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载。
第一处理模块1503,用于对所述上行数据包执行PDCP层的功能。
可选的,所述第一处理模块用于获知所述上行数据包的承载类型;
在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;
在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
可选的,本发明实施例的无线网络节点还包括:
第二接收模块,用于接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
第二处理模块,用于对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
可选的,本发明实施例的无线网络节点还包括:
第一切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;
向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,
以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向所述第一无线网络节点返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
可选的,本发明实施例的无线网络节点还包括:
第二切换模块,用于在所述UE满足切换条件的情况下,确定待切换的目标无线网络节点;
向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息;
根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向所述第一无线网络节点返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
本发明实施例和方法实施例五基于同一构思,其带来的技术效果也相同,具体过程请参照方法实施例五的描述,此处不再赘述。
参见图16,为本发明第四实施例提供的一种无线网络节点的结构示意图,在本发明实施例中,所述无线网络节点包括:第一接收模块1601、识别模块1602和第一处理模块1603。
第一接收模块1601,用于接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息。
识别模块1602,用于根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载。
第一处理模块1603,用于对所述下行数据包执行PDCP层的以下层的功能。
可选的,本发明实施例的无线网络节点还包括:
第二接收模块,用于接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
第二处理模块,用于对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
可选的,本发明实施例的无线网络节点还包括:
切换模块,用于将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向所述第二无线网络节点返回携带所述目标无线网络节点的身份标识的切换指示;
接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
本发明实施例和方法实施例六基于同一构思,其带来的技术效果也相同,具体过程请参照方法实施例六的描述,此处不再赘述。
参见图17为本发明第五实施例还提供了一种无线网络节点,在本发明实施例中,无线网络节点包括处理器171、存储器173和通信接口172。通信接口172用于与外部设备进行通信。无线网络节点17中的处理器的数量可以是一个或多个。本发明的一些实施例中,处理器171、存储器173和通信接口172可通过总线或其他方式连接。无线网络节点可以用于执行图4所示的方法。关于本实施例涉及的术语的含义以及举例,可以参考图4对应的实施例。此处不再赘述。
其中,存储器173中存储程序代码。处理器171用于调用存储器173中存储的程序代码,用于执行以下操作:
获知下行数据包的承载类型;
在所述承载类型为信令无线承载SRB的情况下,将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行分组数据汇聚协议PDCP层的功能;或者
在所述承载类型为数据无线承载DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
在本发明的一些实施例中,所述处理器还用于:
接收所述第二无线网络节点发送的上行数据包;其中,所述第二无线网络节点对所述上行数据包执行物理PHY层的功能、介质访问控制MAC层的功能和逻辑链路控制RLC层的功能,所述上行数据包的承载类型为DRB;
对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
在本发明的一些实施例中,所述处理器还用于:
从所述核心网获取DRB安全信息和SRB安全信息,存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;
其中,对所述下行数据包执行PDCP层的功能包括:
根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
在本发明的一些实施例中,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、完整性校验算法、加密算法、解密算法和安全密钥中的一种或多种。
在本发明的一些实施例中,所述处理器执行所述获知下行数据包的承载类型之前,还用于执行:
接收所述第二无线网络节点发送的用户设备标识和连接请求;
在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
在本发明的一些实施例中,所述处理器还用于:
在所述用户设备满足切换条件的情况下,从所辖的无线网络节点集合中确
定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;
从所述第二无线网络节点获取业务数据的传输状态参数;
在所述用户设备完成切换操作后,根据所述传输状态参数经由所述目标无线接网络节点与所述用户设备传输业务数据。
在本发明的一些实施例中,所述处理器执行从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点包括:
获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:参考信号接收功率RSRP、接收信号强度指示RSSI和参考信号接收质量RSRQ中的一种或多种。
参见图18本发明第六实施例还提供了一种无线网络节点,在本发明实施例中,无线网络节点包括处理器181、存储器183和通信接口182。通信接口182用于与外部设备进行通信。无线网络节点18中的处理器的数量可以是一个或多个。本发明的一些实施例中,处理器181、存储器183和通信接口182可通过总线或其他方式连接。无线网络节点可以用于执行图5所示的方法。关于本实施例涉及的术语的含义以及举例,可以参考图5对应的实施例。此处不再赘述。
其中,183存储器中存储程序代码。181处理器用于调用存储器183中存储的程序代码,用于执行以下操作:
获知用户设备发送的上行数据包的承载类型;
在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;或
在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
在本发明的一些实施例中,所述处理器执行对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能包括:
接收所述第一无线网络节点发送的SRB安全信息,根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
在本发明的一些实施例中,所述处理器还用于执行:
接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;
对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
在本发明的一些实施例中,所述处理器还用于执行:
将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;
接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;
根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向返回连接建立完成消息;
将接收到的连接建立完成消息发送至所述第一无线网络节点。
在本发明的一些实施例中,所述处理器还用于执行:
在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;
向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向返回切换命令消息;
向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
在本发明的一些实施例中,所述处理器执行在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点包括:
在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或
在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备
满足切换条件;或
在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足切换条件;
接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
参见图19本发明第七实施例还提供了一种无线网络节点,在本发明实施例中,无线网络节点包括处理器191、存储器193和通信接口192。通信接口192用于与外部设备进行通信。无线网络节点19中的处理器的数量可以是一个或多个。本发明的一些实施例中,处理器191、存储器193和通信接口可通过总线或其他方式连接。无线网络节点可以用于执行图8所示的方法。关于本实施例涉及的术语的含义以及举例,可以参考图8对应的实施例。此处不再赘述。
其中,193存储器中存储程序代码。处理器181用于调用存储器183中存储的程序代码,用于执行以下操作:
接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;
对所述上行数据包执行PDCP层的功能。
在本发明的一些实施例中,所述处理器执行对所述上行数据包完成PDCP层的功能包括:
获知所述上行数据包的承载类型;
在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;
在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
在本发明的一些实施例中,所述处理器还用于执行:
接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
所述第一无线网节点对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
在本发明的一些实施例中,所述处理器还用于执行:
在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;
向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
在本发明的一些实施例中,所述处理器还用于执行:
在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;
向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向发送携带所述UE上下文信息的切换要求消息;
根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向返回切换响应消息;
接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
参见图20本发明第八实施例还提供了一种无线网络节点,在本发明实施例中,无线网络节点20包括处理器201、存储器203和通信接口202。通信接口202用于与外部设备进行通信。无线网络节点20中的处理器的数量可以是一个或多个。本发明的一些实施例中,处理器201、存储器203和通信接口202可通过总线或其他方式连接。无线网络节点可以用于执行图9所示的方法。关
于本实施例涉及的术语的含义以及举例,可以参考图9对应的实施例。此处不再赘述。
其中,存储器203中存储程序代码。处理器201用于调用存储器202中存储的程序代码,用于执行以下操作:
接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;
根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载;
对所述下行数据包执行PDCP层的以下层的功能。
在本发明的一些实施例中,所述处理器还用于:
接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;
对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
在本发明的一些实施例中,所述处理器还用于:
将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备是否满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向返回携带所述目标无线网络节点的身份标识的切换指示;
接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
本领域普通技术人员可以理解实现上述实施例方法中的全部或部分流程,是可以通过计算机程序来指令相关的硬件来完成,所述的程序可存储于一计算机可读取存储介质中,该程序在执行时,可包括如上述各方法的实施例的流程。其中,所述的存储介质可为磁碟、光盘、只读存储记忆体(Read-Only Memory,ROM)或随机存储记忆体(Random Access Memory,RAM)等。
以上所揭露的仅为本发明一种较佳实施例而已,当然不能以此来限定本发明之权利范围,本领域普通技术人员可以理解实现上述实施例的全部或部分流程,并依本发明权利要求所作的等同变化,仍属于发明所涵盖的范围。
Claims (51)
- 一种数据传输方法,其特征在于,包括:第一无线网络节点获知下行数据包的承载类型;在所述承载类型为信令无线承载SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行分组数据汇聚协议PDCP层的功能;或者在所述承载类型为数据无线承载DRB的情况下,所述第一无线网络节点对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
- 如权利要求1所述的方法,其特征在于,还包括:所述第一无线网络节点接收所述第二无线网络节点发送的上行数据包;其中,所述第二无线网络节点对所述上行数据包执行物理PHY层的功能、介质访问控制MAC层的功能和逻辑链路控制RLC层的功能,所述上行数据包的承载类型为DRB;所述第一无线网络节点对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
- 如权利要求1或2所述的方法,其特征在于,还包括:所述第一无线网络节点从所述核心网获取DRB安全信息和SRB安全信息,所述第一无线网络节点存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;其中,所述第一无线网络节点对所述下行数据包执行PDCP层的功能包括:所述第一无线网络节点根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
- 如权利要求3所述的方法,其特征在于,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、完整性校验算法、加密算法、解密算法 和安全密钥中的一种或多种。
- 如权利要求1所述的方法,其特征在于,所述第一无线网络节点获知下行数据包的承载类型之前,还包括:所述第一无线网络节点接收所述第二无线网络节点发送的用户设备标识和连接请求;在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,所述第一无线网络节点向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
- 如权利要求1-5任意一项所述的方法,其特征在于,还包括:在所述用户设备满足切换条件的情况下,所述第一无线网络节点从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;所述第一无线网络节点从所述第二无线网络节点获取业务数据的传输状态参数;在所述用户设备完成切换操作后,所述第一无线网络节点根据所述传输状态参数经由所述目标无线接网络节点与所述用户设备传输业务数据。
- 如权利要求6所述的方法,其特征在于,所述第一无线网络节点从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点包括:所述第一无线网络节点获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:参考信号接收功率RSRP、接收信号强度指示RSSI和参考信号接收质量RSRQ中的一种或多种。
- 一种无线网络节点,其特征在于,包括:识别模块,用于获知下行数据包的承载类型;第一发送模块,用于在所述承载类型为SRB的情况下,所述第一无线网络节点将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行PDCP层的功能;或第一处理模块,用于在所述承载类型为DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
- 如权利要求8所述的节点,其特征在于,还包括:接收模块,用于接收所述第二无线网络节点发送的上行数据包;其中,所述第二无线网络节点对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,所述上行数据包的承载类型为DRB;第二处理模块,用于对所述上行数据包执行PDCP层的功能,并将处理后上行数据包发送给所述核心网。
- 如权利要求8或9所述的节点,其特征在于,还包括:安全信息获取模块,用于从所述核心网获取DRB安全信息和SRB安全信息,所述第一无线网络节点存储所述DRB安全信息,以及将所述SRB安全信息发送给所述第二无线网络节点;其中,所述第一处理模块用于根据所述DRB安全信息对所述下行数据包执行PDCP层的功能。
- 如权利要求10所述的节点,其特征在于,所述SRB安全信息和所述DRB安全信息包括:整性保护算法、完整性校验算法、加密算法、解密算法和安全密钥中的一种或多种。
- 如权利要求8所述的节点,其特征在于,还包括:SRB建立模块,用于接收所述第二无线网络节点发送的用户设备标识和 连接请求;在所述用户设备标识对应的用户设备具有接入所述第二无线网络节点的权限的情况下,向所述第二无线网络节点返回携带所述用户设备标识的准入指示,所述准入指示用于指示所述用户设备与所述第二无线网络节点之间建立SRB。
- 如权利要求8-12任意一项所述的节点,其特征在于,还包括:切换模块,用于在所述用户设备满足切换条件的情况下,从所辖的无线网络节点集合中确定除所述第二无线网络节点之外的目标无线网络节点,并将所述目标无线网络节点的标识发送至所述第二无线网络节点;从所述第二无线网络节点获取业务数据的传输状态参数;在所述用户设备完成切换操作后,根据所述传输状态参数经由所述目标无线接网络节点与所述用户设备传输业务数据。
- 如权利要求13所述的节点,其特征在于,所述切换模块用于获取所述无线网络节点集合中各个无线网络节点与所述用户设备之间的链路质量参数,选择链路质量参数最优的无线网络节点作为所述目标无线网络节点;其中,所述链路质量参数包括:RSRP、RSSI和RSRQ中的一种或多种。
- 一种无线网络节点,其特征在于,包括存储器和处理器,其特征在于,所述存储器保存有实现如权利要求1-7任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如权利要求1-7任意一项所述的数据传输方法。
- 一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:获知下行数据包的承载类型;在所述承载类型为信令无线承载SRB的情况下,将所述下行数据包发送给第二无线网络节点,以使所述第二无线网络节点对所述下行数据包执行分组数据汇聚协议PDCP层的功能;或者在所述承载类型为数据无线承载DRB的情况下,对所述下行数据包执行PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点。
- 一种数据传输方法,其特征在于,包括:第二无线网络节点获知用户设备发送的上行数据包的承载类型;在所述承载类型为SRB的情况下,所述第二无线网络节点对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;或在所述承载类型为DRB的情况下,所述第二无线网络节点对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
- 如权利要求17所述的方法,其特征在于,所述第二无线网络节点对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能包括:所述第二无线网络节点接收所述第一无线网络节点发送的SRB安全信息,根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
- 如权利要求17或18所述的方法,其特征在于,还包括:所述第二无线网络节点接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;所述第二无线网络节点对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
- 如权利要求17所述的方法,其特征在于,还包括:所述第二无线网络节点将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;所述第二无线网络节点接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;所述第二无线网络节点根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向所述第二无线网络节点返回连接建立完成消息;所述第二无线网络节点将接收到的连接建立完成消息发送至所述第一无线网络节点。
- 如权利要求18所述的方法,其特征在于,还包括:所述第二无线网络节点在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;所述第二无线网络节点向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向所述第二无线网络节点返回切换命令消息;所述第二无线网络节点向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
- 如权利要求21所述的方法,其特征在于,所述第二无线网络节点在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点包括:所述第二无线网络节点在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或所述第二无线网络节点在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备满足切换条件;或所述第二无线网络节点在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足切换条件;所述第二无线网络节点接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
- 一种无线网络节点,其特征在于,包括:识别模块,用于获知用户设备发送的上行数据包的承载类型;第一处理模块,用于在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;或第一发送模块,用于在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
- 如权利要求23所述的节点,其特征在于,所述第一处理模块用于接收所述第一无线网络节点发送的SRB安全信息,根据所述SRB安全信息对所述上行数据包执行PDCP层的功能。
- 如权利要求22或23所述的节点,其特征在于,还包括:接收模块,用于接收所述第一无线网络节点发送的下行数据包;其中,所述下行数据包的承载类型为SRB;第二处理模块,用于对所述下行数据包执行RRC层的功能以及所述RRC层的以下层的功能,并将处理后的下行数据包发送给用户设备。
- 如权利要求22所述的节点,其特征在于,还包括:SRB建立模块,用于将所述用户设备发送的携带用户设备标识的连接请求转发至所述第一无线网络节点;接收所述第一无线网络节点在确定所述用户设备具有接入权限后生成的准入指示;其中,所述准入指示携带所述用户设备标识;根据所述准入指示生成连接建立消息,并将所述连接建立消息发送给所述用户设备,以使所述用户设备根据所述连接建立消息建立SRB,并在成功建立SRB后,向所述第二无线网络节点返回连接建立完成消息;将接收到的连接建立完成消息发送至所述第一无线网络节点。
- 如权利要求23所述的节点,其特征在于,还包括:切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;向所述目标无线网络节点发送携带所述SRB安全信息的切换请求消息,以使所述目标无线网络节点在准备好切换资源后,向所述第二无线网络节点返回切换命令消息;向所述用户设备转发所述切换命令消息,其中,所述切换命令消息携带所述SRB安全信息,以使所述用户设备在完成切换操作后向所述目标无线网络节点返回切换完成消息,所述目标无线网络接入节点接收到所述切换完成消息后,根据所述SRB安全信息对信令数据进行安全保护。
- 如权利要求27所述的节点,其特征在于,所述切换模块用于:在所述用户设备的信号载波电平小于第一阈值的情况下,确定所述用户设备满足切换条件;或在所述用户设备的信号载干比小于第二阈值的情况下,确定所述用户设备满足切换条件;或在与所述用户设备的距离大于第三阈值的情况下,确定所述用户设备满足切换条件;接收所述第一无线网络节点发送的携带所述目标无线网络节点的身份标识,根据所述身份标识确定所述目标网线网络节点。
- 一种无线网络节点,其特征在于,包括存储器和处理器,其特征在于,所述存储器保存有实现如权利要求17-22任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如权利要求17-22任意一项所述的数据传输方法。
- 一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:获知用户设备发送的上行数据包的承载类型;在所述承载类型为SRB的情况下,对所述上行数据包执行PHY层的功能以及所述PHY层的以上层的功能;或在所述承载类型为DRB的情况下,对所述上行数据包执行PHY层的功能、MAC层的功能和RLC层的功能,并将处理后的上行数据包发送给第一无线网络节点,以使所述第一无线网络节点对所述处理后的上行数据包执行PDCP层的功能。
- 一种数据的传输方法,其特征在于,包括:第一无线网络节点接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;所述第一无线网络节点根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;所述第一无线网络节点对所述上行数据包执行PDCP层的功能。
- 如权利要求31所述的方法,其特征在于,所述第一无线网络节点对所述上行数据包完成PDCP层的功能包括:所述第一无线网络节点获知所述上行数据包的承载类型;在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
- 如权利要求32所述的方法,其特征在于,还包括:所述第一无线网络节点接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;所述第一无线网节点对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
- 如权利要求31-33任意一项所述的方法,其特征在于,还包括:在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;所述第一无线网络节点向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向所述第一无线网络节点返回切换响应消息;所述第一无线网络节点接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
- 如权利要求33-34任意一项所述的方法,其特征在于,还包括:在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点;所述第一无线网络节点向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息;所述第一无线网络节点根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向所述第一无线网络节点返回切换响应消息;所述第一无线网络节点接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
- 一种无线网络节点,其特征在于,包括:第一接收模块,用于接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份 信息的第一指示信息;识别模块,用于根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;第一处理模块,用于对所述上行数据包执行PDCP层的功能。
- 如权利要求36所述的节点,其特征在于,所述第一处理模块用于获知所述上行数据包的承载类型;在所述上行数据包的承载类型为DRB的情况下,根据DRB安全信息对所述第二数据包执行PDCP层的功能,将处理后的上行数据包发送给核心网;在所述上行数据包的承载类型为SRB的情况下,根据SRB安全信息对所述第二数据包执行PDCP层的功能和RRC层的功能。
- 如权利要求36或37所述的节点,其特征在于,还包括:第二接收模块,用于接收所述核心网发送的下行数据包,其中,所述下行数据包携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;第二处理模块,用于对所述数据包完成RRC层的功能和PDCP层的功能,并将处理后的下行数据包发送给所述第二无线网络节点,以使所述第二无线网络节点根据所述第二指示信息获知下行数据包的用户设备、承载类型和承载。
- 如权利要求36-38任意一项所述的节点,其特征在于,还包括:第一切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点以及获取所述第二无线网络节点的UE上下文信息;向所述目标无线网络节点发送携带所述UE上下文信息的切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限并准备好切换资源后,向所述第一无线网络节点返回切换响应消息;接收所述目标无线网络节点返回的切换响应消息转发至所述第二无线网络节点,以使所述第二无线网络节点根据所述切换响应消息向所述用户设备发 送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
- 如权利要求36-38任意一项所述的节点,其特征在于,还包括:第二切换模块,用于在所述用户设备满足切换条件的情况下,确定待切换的目标无线网络节点;向所述第二无线网络节点发送携带所述目标无线网络节点的标识的切换指示消息,所述切换指示消息用于指示所述无线网络节点获取所述用户设备的UE上下文信息,并向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息;根据所述切换要求消息向所述目标无线网络节点发送切换请求消息,以使所述目标无线网络节点在确定所述用户设备具有接入权限后,向所述第一无线网络节点返回切换响应消息;接收所述目标无线网络节点返回的切换响应消息后,将所述切换响应消息发送至所述第二无线网络节点,以使所述无线网络节点根据所述切换响应消息向所述用户设备发送切换命令消息,所述切换命令消息用于指示所述用户设备完成切换操作。
- 一种无线网络节点,其特征在于,包括存储器和处理器,其特征在于,所述存储器保存有实现如权利要求31-35任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如权利要求31-35任意一项所述的数据传输方法。
- 一种存储介质,用于控制计算机设备执行数据传输方法,所述方法包括以下步骤:接收第二无线网络设备发送的上行数据包,其中,所述上行数据包中携带表示用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;根据所述第一指示信息获知所述上行数据包对应的用户设备、承载类型以及承载;对所述上行数据包执行PDCP层的功能。
- 一种数据传输方法,其特征在于,包括:第二无线网络节点接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;所述第二无线网络节点根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载;所述第二无线网络节点对所述下行数据包执行PDCP层的以下层的功能。
- 如权利要求43所述的方法,其特征在于,还包括:所述第二无线网络节点接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;所述第二无线网络节点对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
- 如权利要求43或44所述的方法,其特征在于,还包括:所述第二无线网络节点将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备是否满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向所述第二无线网络节点返回携带所述目标无线网络节点的身份标识的切换指示;所述第二无线网络节点接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
- 一种无线网络节点,其特征在于,包括:第一接收模块,用于接收所述第一无线网络节点发送的下行数据包,其中, 所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;识别模块,用于根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载;第一处理模块,用于对所述下行数据包执行PDCP层的以下层的功能。
- 如权利要求46所述的节点,其特征在于,还包括:第二接收模块,用于接收用户设备发送的上行数据包,其中,所述上行数据包携带表示所述用户设备的身份信息、承载的类型信息和承载的身份信息的第二指示信息;第二处理模块,用于对所述上行数据包执行PDCP层的以下层的功能,并将处理后的上行数据包发送给所述第一无线网络节点,以使所述第一无线网络节点对处理后的上行数据包执行PDCP层的功能。
- 如权利要求46或47所述的节点,其特征在于,还包括:切换模块,用于将所述用户设备发送的测量报告转发给所述第一无线网络节点,以使所述第一无线网络节点根据所述测量报告在所述用户设备满足切换条件的情况下,所述第一无线网络节点确定待切换的目标无线网络节点,所述第一无线网络节点向所述第二无线网络节点返回携带所述目标无线网络节点的身份标识的切换指示;接收到所述携带所述目标无线网络节点的身份标识的切换指示后,获取所述用户设备的UE上下文信息以及向所述第一无线网络节点发送携带所述UE上下文信息的切换要求消息。
- 一种无线网络节点,其特征在于,包括存储器和处理器,其特征在于,所述存储器保存有实现如权利要求43-45任意一项所述的数据传输方法的指令,所述处理器调取并执行所述存储器中的指令,实现如权利要求43-45任意一项所述的数据传输方法。
- 一种存储介质,用于控制计算机设备执行手势控制方法,所述方法包括以下步骤:接收所述第一无线网络节点发送的下行数据包,其中,所述下行数据包携带标识用户设备的身份信息、承载的类型信息和承载的身份信息的第一指示信息;根据所述第一指示信息获知所述下行数据包对应的用户设备、承载类型和承载;对所述下行数据包执行PDCP层的以下层的功能。
- 一种通信系统,其特征在于,包括:如权利要求8-15任意一项所述的无线网络节点和至少一个如权利要求23-29的无线网络节点;或如权利要求36-41的任意一项所述的无线网络节点和至少一个如权利要求46-49任意一项所述的无线网络节点。
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JP6933350B2 (ja) | 2021-09-08 |
CN106332048B (zh) | 2022-08-19 |
EP3300443B1 (en) | 2020-05-27 |
EP3300443A1 (en) | 2018-03-28 |
CN106332048A (zh) | 2017-01-11 |
US20180124647A1 (en) | 2018-05-03 |
PL3300443T3 (pl) | 2020-11-16 |
CN115474245A (zh) | 2022-12-13 |
ZA201708698B (en) | 2018-11-28 |
US10834638B2 (en) | 2020-11-10 |
EP3300443A4 (en) | 2018-06-20 |
JP2018519741A (ja) | 2018-07-19 |
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