WO2016132561A1 - 無線通信システム、基地局および移動局 - Google Patents
無線通信システム、基地局および移動局 Download PDFInfo
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- H—ELECTRICITY
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- H04W76/10—Connection setup
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
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- H04W28/02—Traffic management, e.g. flow control or congestion control
- H04W28/0268—Traffic management, e.g. flow control or congestion control using specific QoS parameters for wireless networks, e.g. QoS class identifier [QCI] or guaranteed bit rate [GBR]
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- H04W88/00—Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
- H04W88/02—Terminal devices
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- H04W28/0252—Traffic management, e.g. flow control or congestion control per individual bearer or channel
- H04W28/0263—Traffic management, e.g. flow control or congestion control per individual bearer or channel involving mapping traffic to individual bearers or channels, e.g. traffic flow template [TFT]
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Definitions
- the present invention relates to a radio communication system, a base station, and a mobile station.
- LTE Long Term Evolution
- WLAN Wireless Local Area Network
- WLAN when WLAN is used, a technique for transferring data from RRC (Radio Resource Control: Radio Resource Control) to a MAC (Media Access Control: Media Access Control) layer is known (for example, see Patent Document 1 below). . Also, a technique for sharing LTE PDCP (Packet Data Convergence Protocol) between LTE and WLAN is known (for example, see Patent Document 2 below). Also, a technique for performing data transmission control based on QoS (Quality of Service) information in a WLAN or the like is known.
- RRC Radio Resource Control: Radio Resource Control
- MAC Media Access Control: Media Access Control
- LTE PDCP Packet Data Convergence Protocol
- QoS Quality of Service
- an object of the present invention is to provide a radio communication system, a base station, and a mobile station that can suppress a decrease in communication quality or can maintain communication quality.
- the base station can perform second wireless communication different from the first wireless communication by a control unit that controls the first wireless communication.
- the mobile station can transmit data to and from the base station using the first wireless communication or the second wireless communication, and the mobile station can transmit data between the base station and the mobile station.
- the processing unit for performing the first wireless communication in the transmitting station of the base station and the mobile station is the first wireless communication
- a wireless communication that establishes a convergence point for performing transmission and transmits the data to the receiving station among the base station and the mobile station by making the quality of service information included in the data transparent at the convergence point System, base station and mobile station are proposed
- FIG. 1 is a diagram of an example of a wireless communication system according to the first embodiment.
- FIG. 2 is a diagram of an example of the wireless communication system according to the second embodiment.
- FIG. 3 is a diagram of an example of a terminal according to the second embodiment.
- FIG. 4 is a diagram of an example of a hardware configuration of the terminal according to the second embodiment.
- FIG. 5 is a diagram of an example of the base station according to the second embodiment.
- FIG. 6 is a diagram of an example of a hardware configuration of the base station according to the second embodiment.
- FIG. 7 is a diagram of an example of a protocol stack in the wireless communication system according to the second embodiment.
- FIG. 8 is a diagram of an example of layer 2 in the wireless communication system according to the second embodiment.
- FIG. 9 is a diagram illustrating an example of an IP header of an IP packet transmitted in the wireless communication system according to the second embodiment.
- FIG. 10 is a diagram illustrating an example of a value of the ToS field included in the IP header of the IP packet transmitted in the wireless communication system according to the second embodiment.
- FIG. 11 is a diagram of an example of aggregation by LTE-A and WLAN in the wireless communication system according to the second embodiment.
- FIG. 12 is a diagram illustrating an example of QoS control based on the ToS field in the wireless communication system according to the second embodiment.
- FIG. 13 is a diagram illustrating an example of AC classification in the wireless communication system according to the second embodiment.
- FIG. 14 is a diagram of an example of offload in the wireless communication system according to the second embodiment.
- FIG. 15 is a diagram illustrating an example of mapping of a QoS class to an AC applicable to the wireless communication system according to the second embodiment.
- FIG. 16 is a flowchart of an example of processing performed by the transmission side device in the wireless communication system according to the second embodiment.
- FIG. 17 is a diagram illustrating an example when a plurality of EPS bearers have the same QoS class in the wireless communication system according to the second embodiment.
- FIG. 18 is a diagram illustrating an example of a method for identifying an EPS bearer using a UL TFT in the wireless communication system according to the third embodiment.
- FIG. 19 is a diagram illustrating another example of the method of identifying the EPS bearer using the UL TFT in the wireless communication system according to the third embodiment.
- FIG. 20 is a diagram illustrating an example of a TFT acquisition method in the wireless communication system according to the third embodiment.
- FIG. 21 is a diagram illustrating an example of a method of identifying an EPS bearer using DL TFTs in the wireless communication system according to the third embodiment.
- FIG. 22 is a diagram illustrating another example of the method of identifying the EPS bearer using the DL TFT in the wireless communication system according to the third embodiment.
- FIG. 23 is a diagram illustrating an example of a method for identifying an EPS bearer using a virtual IP flow in the wireless communication system according to the third embodiment.
- FIG. 24 is a diagram illustrating another example of the method of identifying the EPS bearer using the virtual IP flow in the wireless communication system according to the third embodiment.
- FIG. 21 is a diagram illustrating an example of a method of identifying an EPS bearer using DL TFTs in the wireless communication system according to the third embodiment.
- FIG. 22 is a diagram illustrating another example of the method of
- FIG. 25 is a diagram illustrating an example of a method for identifying an EPS bearer using a VLAN in the wireless communication system according to the third embodiment.
- FIG. 26 is a diagram illustrating another example of the method for identifying the EPS bearer using the VLAN in the wireless communication system according to the third embodiment.
- FIG. 27 is a diagram illustrating an example of a method of identifying an EPS bearer using GRE tunneling in the wireless communication system according to the third embodiment.
- FIG. 28 is a diagram illustrating another example of a method for identifying an EPS bearer using GRE tunneling in the wireless communication system according to the third embodiment.
- FIG. 1 is a diagram of an example of a wireless communication system according to the first embodiment.
- the wireless communication system 100 includes a base station 110 and a mobile station 120.
- data transmission using the first wireless communication 101 and data transmission using the second wireless communication 102 are possible between the base station 110 and the mobile station 120.
- the first wireless communication 101 and the second wireless communication 102 are different wireless communication (wireless communication system).
- the first wireless communication 101 is, for example, cellular communication such as LTE or LTE-A.
- the second wireless communication 102 is, for example, a WLAN.
- the first wireless communication 101 and the second wireless communication 102 are not limited to these, and various types of communication can be used.
- the base station 110 is a base station capable of performing the first wireless communication 101 and the second wireless communication 102 with the mobile station 120, for example.
- the base station 110 and the mobile station 120 When transmitting data using the first wireless communication 101 without using the first wireless communication 102, the base station 110 and the mobile station 120 transmit the first wireless communication 101 data first.
- the communication path of the wireless communication 101 is set between the base station 110 and the mobile station 120. Then, the base station 110 and the mobile station 120 transmit data through the set communication path of the first wireless communication 101.
- the base station 110 and the mobile station 120 use the communication path of the second wireless communication 102 for transmitting the data of the first wireless communication 101. It is set between the base station 110 and the mobile station 120. Then, the base station 110 and the mobile station 120 transmit data through the set communication path of the second wireless communication 102.
- the base station 110 includes a control unit 111 and a processing unit 112.
- the control unit 111 controls the first wireless communication 101.
- the control unit 111 controls the second wireless communication 102.
- the control unit 111 is a processing unit such as RRC that performs radio control between the base station 110 and the mobile station 120.
- the control unit 111 is not limited to RRC, and can be various processing units that control the first wireless communication 101.
- the processing unit 112 performs processing for performing the first wireless communication 101.
- the processing unit 112 is a processing unit of a data link layer such as PDCP, RLC (Radio Link Control), and MAC.
- the processing unit 112 is not limited to these, and can be various processing units for performing the first wireless communication 101.
- the processing of the processing unit 112 for performing the first wireless communication 101 is controlled by the control unit 111.
- the processing unit 112 establishes a convergence point for performing the first wireless communication 101 when data is transmitted from the base station 110 to the mobile station 120 using the wireless communication of the second wireless communication 102.
- This convergence point is a process for selecting data to be transmitted between the base station 110 and the mobile station 120 between the first wireless communication 101 and the second wireless communication 102 (presence of offload described later). is there.
- the convergence point is sometimes called a termination point, a branch point, a split function, or a routing function. If the meaning is to serve as a schedule point for data in the first wireless communication and the second wireless communication, such a name is used. Not limited to. Hereinafter, the convergence point is used as such a representative name.
- the processing unit 112 transmits the data to the mobile station 120 through the service quality information included in the data transmitted to the mobile station 120 at the established convergence point.
- the quality-of-service information is information indicating the priority of transmission such as a data service class.
- the service quality information is QoS information such as a ToS (Type of Service) field included in the header of the data.
- the service quality information is not limited to this, and may be various information indicating the priority of data transmission.
- a VLAN Virtual Local Area Network
- a VLAN tag defines a field for defining QoS therein.
- the QoS information is information set with a 5-tuple.
- the 5-tuple is a source IP address and port number, a destination IP address and port number, and a protocol type.
- the processing unit 112 when transmitting data from the base station 110 to the mobile station 120 using the first wireless communication 101 without using the second wireless communication 102, the processing unit 112 performs predetermined processing on the data to be transmitted.
- the predetermined process is, for example, a process that makes it impossible to refer to service quality information included in data to be transmitted in the process of the second wireless communication 102.
- the predetermined process is a process including at least one of concealment, header compression, and addition of a sequence number.
- the predetermined process is a PDCP process.
- the predetermined processing is not limited to this, and various types of processing that make it impossible to refer to the service quality information in the processing of the second wireless communication 102 can be used.
- the processing unit 112 when transmitting data to the mobile station 120 using the second wireless communication 102, refers to the service quality information included in the data to be transmitted with respect to the data to be transmitted.
- the above-described predetermined processing that cannot be performed in the processing of the communication 102 is not performed.
- the service quality information can be referred to in the processing of the second wireless communication 102.
- transmission control based on service quality information can be performed for the data to be transmitted in the processing of the second wireless communication 102.
- the transmission control based on the service quality information is, for example, QoS control for controlling the priority of transmission according to the service quality information.
- the transmission control based on the service quality information is not limited to this and can be various types of control.
- the mobile station 120 receives data transmitted from the base station 110 by at least one of the first wireless communication 101 and the second wireless communication 102. As described above, the data transmission efficiency from the base station 110 to the mobile station 120 can be improved by distributing the data to the first wireless communication 101 and the second wireless communication 102.
- the mobile station 120 includes a processing unit 121.
- the processing unit 121 is a processing unit for performing the first wireless communication 101 similarly to the processing unit 112 of the base station 110.
- the processing unit 121 is a data link layer processing unit such as PDCP, RLC, or MAC.
- the processing unit 121 is not limited to these, and can be various processing units for performing the first wireless communication 101.
- the processing of the processing unit 121 for performing the first wireless communication 101 is controlled by the control unit 111 of the base station 110.
- the processing unit 121 establishes a convergence point for performing the first wireless communication 101 when transmitting data from the mobile station 120 to the base station 110 using the wireless communication of the second wireless communication 102.
- this convergence point is selected between the first wireless communication 101 and the second wireless communication 102 for data transmitted between the base station 110 and the mobile station 120 (presence of offload described later). This is also called a terminal point or a branch point.
- the processing unit 121 transmits the data to the base station 110 through the service quality information included in the data transmitted to the base station 110 at the established convergence point.
- the service quality information is information indicating the priority of transmission such as a data service class.
- the processing unit 121 performs predetermined processing on the data to be transmitted. I do.
- the predetermined process is a process for making it impossible to refer to the service quality information included in the data to be transmitted in the process of the second wireless communication 102.
- the processing unit 121 when transmitting data to the base station 110 using the second wireless communication 102, the processing unit 121 refers to the service quality information included in the transmitted data with respect to the transmitted data.
- the above-described predetermined processing that is disabled in the processing of the communication 102 is not performed.
- the quality of service information can be referred to in the processing of the second wireless communication 102 for the data transmitted using the second wireless communication 102.
- transmission control based on service quality information can be performed for the data to be transmitted in the processing of the second wireless communication 102.
- the transmission control based on the service quality information is, for example, QoS control for controlling the priority of transmission according to the service quality information as described above.
- the base station 110 receives data transmitted from the mobile station 120 by at least one of the first wireless communication 101 and the second wireless communication 102. As described above, the data transmission efficiency from the mobile station 120 to the base station 110 can be improved by distributing the data to the first wireless communication 101 and the second wireless communication 102.
- the transmitting station Service quality information is made transparent in the processing unit of one wireless communication 101.
- the transmitting station of the base station 110 and the mobile station 120 can perform transmission control according to the service quality information in the data transmission processing in the second wireless communication 102. For this reason, it is possible to suppress deterioration in communication quality due to data transmission using the second wireless communication 102 or to maintain communication quality.
- the base station 110 is a base station capable of performing the first wireless communication 101 and the second wireless communication 102 with the mobile station 120 .
- base stations 110A and 110B may be provided in place of the base station 110.
- the base station 110 ⁇ / b> A is a base station capable of performing the first wireless communication 101 with the mobile station 120.
- the base station 110B is a base station connected to the base station 110A, and is a base station capable of performing the second wireless communication 102 with the mobile station 120.
- the base station 110A performs data transmission via the base station 110B when performing data transmission using the second wireless communication 102 with the mobile station 120.
- the control unit 111 and the processing unit 112 illustrated in FIG. 1A are provided in the base station 110A, for example.
- the control unit 111 controls the second wireless communication 102 with the mobile station 120 via the base station 110B.
- the processing unit 112 of the base station 110A transmits the data to the base station 110B by making the quality of service information included in the data transmitted to the mobile station 120 transparent at the established convergence point.
- the data is transmitted to the mobile station 120 via 110B.
- the base station 110 ⁇ / b> B transmits the data transferred from the base station 110 ⁇ / b> A to the mobile station 120 through the second wireless communication 102.
- the processing of the processing unit 121 of the mobile station 120 is controlled by the control unit 111 of the base station 110A. Then, at the established convergence point, the processing unit 121 transmits the service quality information included in the data to the base station 110 ⁇ / b> A through the second wireless communication 102 to the base station 110 ⁇ / b> B.
- the base station 110B transfers the data transmitted from the mobile station 120 through the second wireless communication 102 to the base station 110A. Thereby, data to base station 110 ⁇ / b> A can be transmitted to base station 110 ⁇ / b> A using wireless communication 102.
- the transmitting station of the base station 110A and the mobile station 120 transmits data using the second wireless communication 102 under the control of the control unit 111 of the first wireless communication 101
- the transmitting station Service quality information is made transparent in the processing unit of one wireless communication 101.
- the base station 110B can perform transmission control according to the service quality information in the data transmission processing by the second wireless communication 102.
- the mobile station 120 can perform transmission control according to the service quality information in the data transmission processing by the second wireless communication 102. For this reason, it is possible to suppress deterioration in communication quality due to data transmission using the second wireless communication 102 or to maintain communication quality.
- Embodiment 1 it is possible to suppress a decrease in communication quality or to maintain communication quality.
- Embodiments 2 and 3 can be regarded as examples of the embodiment 1 described above, it goes without saying that the embodiments 2 and 3 can be implemented in combination with the embodiment 1.
- FIG. 2 is a diagram of an example of the wireless communication system according to the second embodiment.
- the radio communication system 200 according to the second embodiment includes a UE 211, eNBs 221 and 222, and a packet core network 230.
- the radio communication system 200 is a mobile communication system such as LTE-A defined in 3GPP, for example, but the communication standard of the radio communication system 200 is not limited to these.
- the packet core network 230 is an EPC (Evolved Packet Core) defined in 3GPP, but is not particularly limited thereto.
- the core network defined in 3GPP may be called SAE (System Architecture Evolution).
- the packet core network 230 includes an SGW 231, a PGW 232, and an MME 233.
- the UE 211 and eNBs 221 and 222 form a radio access network by performing radio communication.
- the radio access network formed by the UE 211 and the eNBs 221 and 222 is, for example, E-UTRAN (Evolved Universal Terrestrial Access Network) defined in 3GPP, but is not particularly limited thereto.
- E-UTRAN Evolved Universal Terrestrial Access Network
- the UE 211 is a terminal that is located in the cell of the eNB 221 and performs wireless communication with the eNB 221. As an example, the UE 211 communicates with other communication devices via a route that passes through the eNB 221, the SGW 231 and the PGW 232. Other communication devices that communicate with the UE 211 are, for example, a communication terminal or a server that is different from the UE 211.
- the communication between the UE 211 and another communication device is, for example, data communication or voice communication, but is not particularly limited thereto.
- the voice communication is, for example, VoLTE (Voice over LTE), but is not particularly limited thereto.
- the eNB 221 is a base station that forms the cell 221a and performs wireless communication with the UE 211 located in the cell 221a.
- the eNB 221 relays communication between the UE 211 and the SGW 231.
- the eNB 222 is a base station that forms the cell 222a and performs radio communication with the UE located in the cell 222a.
- the eNB 222 relays communication between the UE located in the cell 222a and the SGW 231.
- the eNB 221 and the eNB 222 may be connected by, for example, a physical or logical interface between base stations.
- the inter-base station interface is an X2 interface as an example, but the inter-base station interface is not particularly limited to this.
- the eNB 221 and the SGW 231 are connected by, for example, a physical or logical interface.
- the interface between the eNB 221 and the SGW 231 is an S1-U interface as an example, but is not particularly limited thereto.
- the SGW 231 is a serving gateway that accommodates the eNB 221 and performs U-plane (User plane) processing in communication via the eNB 221.
- U-plane User plane
- the SGW 231 performs U-plane processing in the communication of the UE 211.
- U-plane is a function group that transmits user data (packet data).
- the SGW 231 may accommodate the eNB 222 and perform U-plane processing in communication via the eNB 222.
- the PGW 232 is a packet data network gateway for connecting to an external network.
- An example of the external network is the Internet, but is not limited thereto.
- the PGW 232 relays user data between the SGW 231 and the external network.
- the PGW 232 performs IP address allocation 201 for assigning an IP address to the UE 211 so that the UE 211 transmits and receives an IP flow.
- the SGW 231 and the PGW 232 are connected by, for example, a physical or logical interface.
- the interface between the SGW 231 and the PGW 232 is an S5 interface as an example, but is not particularly limited thereto.
- MME 233 Mobility Management Entity accommodates eNB 221 and performs C-plane (Control Plane) processing in communication via eNB 221.
- C-plane Control Plane
- the MME 233 performs C-plane processing in communication of the UE 211 via the eNB 221.
- C-plane is a function group for controlling calls and networks between devices, for example.
- the C-plane is used for packet call connection, setting of a route for transmitting user data, handover control, and the like.
- the MME 233 may accommodate the eNB 222 and perform C-plane processing in communication via the eNB 222.
- the MME 233 and the eNB 221 are connected by, for example, a physical or logical interface.
- the interface between the MME 233 and the eNB 221 is an S1-MME interface as an example, but is not particularly limited thereto.
- the MME 233 and the SGW 231 are connected by, for example, a physical or logical interface.
- the interface between the MME 233 and the SGW 231 is an S11 interface as an example, but is not particularly limited thereto.
- IP flows transmitted or received by the UE 211 are classified (sorted) into EPS bearers 241 to 24n and transmitted via the PGW 232 and the SGW 231.
- the EPS bearers 241 to 24n are IP flows in EPS (Evolved Packet System).
- the EPS bearers 241 to 24n are radio bearers 251 to 25n (Radio Bearer) in the radio access network formed by the UE 211 and the eNBs 221 and 222. Control of the entire communication such as setting of the EPS bearers 241 to 24n, setting of security, management of mobility, and the like is performed by the MME 233.
- the IP flows classified into the EPS bearers 241 to 24n are transmitted in the LTE network by, for example, a GTP (GPRS Tunneling Protocol) tunnel set between the nodes.
- GTP GPRS Tunneling Protocol
- the EPS bearers 241 to 24n are uniquely mapped to the radio bearers 251 to 25n, and are wirelessly transmitted in consideration of QoS.
- the first wireless communication 101 shown in FIG. 1 can be wireless communication based on LTE-A, for example.
- the second wireless communication 102 shown in FIG. 1 can be wireless communication by WLAN, for example.
- the aggregation by LTE-A and WLAN will be described later.
- aggregation is an example, and is often used in the sense of using a plurality of communication frequencies (carriers). Apart from aggregation, it is often called integration in the sense that multiple systems are integrated and used. Hereinafter, aggregation is used as a representative name.
- the base station 110 shown in FIG. 1 can be realized by eNBs 221 and 222, for example.
- the mobile station 120 illustrated in FIG. 1 can be realized by the UE 211, for example.
- FIG. 3 is a diagram of an example of a terminal according to the second embodiment.
- the UE 211 shown in FIG. 2 can be realized by the terminal 300 shown in FIG. 3, for example.
- the terminal 300 includes a wireless communication unit 310, a control unit 320, and a storage unit 330.
- the wireless communication unit 310 includes a wireless transmission unit 311 and a wireless reception unit 312. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.
- the wireless communication unit 310 can perform, for example, wireless communication using LTE-A (first wireless communication 101) and wireless communication using WLAN (second wireless communication 102).
- the wireless transmission unit 311 transmits user data and control signals by wireless communication via an antenna.
- the radio signal transmitted by the radio transmission unit 311 can include arbitrary user data, control information, and the like (encoded or modulated).
- the wireless reception unit 312 receives user data and control signals by wireless communication via an antenna.
- the radio signal received by the radio reception unit 312 can include arbitrary user data, a control signal, and the like (encoded or modulated).
- the antenna may be common for transmission and reception.
- the control unit 320 outputs user data and control signals to be transmitted to other wireless stations to the wireless transmission unit 311. In addition, the control unit 320 acquires user data and control signals received by the wireless reception unit 312. The control unit 320 inputs and outputs user data, control information, programs, and the like with the storage unit 330 described later. In addition, the control unit 320 inputs / outputs user data and control signals transmitted / received to / from other communication devices and the like with a communication unit described later. In addition to these, the control unit 320 performs various controls in the terminal 300.
- the storage unit 330 stores various information such as user data, control information, and programs.
- the processing unit 121 of the mobile station 120 illustrated in FIG. 1 can be realized by the control unit 320, for example.
- FIG. 4 is a diagram illustrating an example of a hardware configuration of a terminal according to the second embodiment.
- the terminal 300 shown in FIG. 3 can be realized by, for example, the terminal 400 shown in FIG.
- the terminal 400 includes, for example, an antenna 411, an RF circuit 412, a processor 413, and a memory 414. These components are connected so that various signals and data can be input / output via a bus, for example.
- the antenna 411 includes a transmission antenna that transmits a radio signal and a reception antenna that receives a radio signal.
- the antenna 411 may be a shared antenna that transmits and receives radio signals.
- the RF circuit 412 performs RF (Radio Frequency: high frequency) processing of a signal received by the antenna 411 and a signal transmitted by the antenna 411.
- the RF processing includes, for example, frequency conversion between the baseband band and the RF band.
- the processor 413 is, for example, a CPU (Central Processing Unit) or a DSP (Digital Signal Processor).
- the processor 413 may be realized by a digital electronic circuit such as an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or an LSI (Large Scale Integration).
- ASIC Application Specific Integrated Circuit
- FPGA Field Programmable Gate Array
- LSI Large Scale Integration
- the memory 414 can be realized by a random access memory (RAM) such as SDRAM (Synchronous Dynamic Random Access Memory), a ROM (Read Only Memory), or a flash memory, for example.
- RAM random access memory
- SDRAM Serial Dynamic Random Access Memory
- ROM Read Only Memory
- flash memory for example.
- the memory 414 stores user data, control information, programs, and the like, for example.
- the wireless communication unit 310 shown in FIG. 3 can be realized by the antenna 411 and the RF circuit 412, for example.
- the control unit 320 illustrated in FIG. 3 can be realized by the processor 413, for example.
- the storage unit 330 illustrated in FIG. 3 can be realized by the memory 414, for example.
- FIG. 5 is a diagram of an example of the base station according to the second embodiment.
- Each of the eNBs 221 and 222 shown in FIG. 2 can be realized by the base station 500 shown in FIG. 5, for example.
- the base station 500 includes, for example, a wireless communication unit 510, a control unit 520, a storage unit 530, and a communication unit 540.
- the wireless communication unit 510 includes a wireless transmission unit 511 and a wireless reception unit 512. Each of these components is connected so that signals and data can be input and output in one direction or in both directions.
- the wireless communication unit 510 can perform, for example, wireless communication using LTE-A (first wireless communication 101) and wireless communication using WLAN (second wireless communication 102).
- the wireless transmission unit 511 transmits user data and control signals by wireless communication via an antenna.
- the wireless signal transmitted by the wireless transmission unit 511 can include arbitrary user data, control information, and the like (encoded or modulated).
- the wireless reception unit 512 receives user data and control signals by wireless communication via an antenna.
- the radio signal received by the radio reception unit 512 can include arbitrary user data, a control signal, and the like (encoded or modulated).
- the antenna may be common for transmission and reception.
- the control unit 520 outputs user data and control signals to be transmitted to other wireless stations to the wireless transmission unit 511. In addition, the control unit 520 acquires user data and control signals received by the wireless reception unit 512. The control unit 520 inputs and outputs user data, control information, programs, and the like with a storage unit 530 described later. In addition, the control unit 520 inputs and outputs user data and control signals transmitted to and received from other communication devices and the like with a communication unit 540 described later. In addition to these, the control unit 520 performs various controls in the base station 500.
- the storage unit 530 stores various information such as user data, control information, and programs.
- the communication unit 540 transmits and receives user data and control signals to and from other communication devices, for example, by wired signals.
- control unit 111 and the processing unit 112 of the base station 110 illustrated in FIG. 1 can be realized by the control unit 520, for example.
- FIG. 6 is a diagram of an example of a hardware configuration of the base station according to the second embodiment.
- the base station 500 shown in FIG. 5 can be realized by, for example, the base station 600 shown in FIG.
- the base station 600 includes an antenna 611, an RF circuit 612, a processor 613, a memory 614, and a network IF 615. These components are connected so that various signals and data can be input / output via a bus, for example.
- the antenna 611 includes a transmission antenna that transmits a radio signal and a reception antenna that receives a radio signal.
- the antenna 611 may be a shared antenna that transmits and receives radio signals.
- the RF circuit 612 performs RF processing on a signal received by the antenna 611 and a signal transmitted by the antenna 611.
- the RF processing includes, for example, frequency conversion between the baseband band and the RF band.
- the processor 613 is, for example, a CPU or a DSP.
- the processor 613 may be realized by a digital electronic circuit such as an ASIC, FPGA, LSI or the like.
- the memory 614 can be realized by a RAM such as SDRAM, a ROM, or a flash memory, for example.
- the memory 614 stores user data, control information, programs, and the like, for example.
- the network IF 615 is a communication interface that performs communication with the network by, for example, a wired connection.
- the network IF 615 may include an Xn interface for performing wired communication between base stations, for example.
- the wireless communication unit 510 shown in FIG. 5 can be realized by the antenna 611 and the RF circuit 612, for example.
- the control unit 520 illustrated in FIG. 5 can be realized by the processor 613, for example.
- the storage unit 530 illustrated in FIG. 5 can be realized by the memory 614, for example.
- the communication unit 540 illustrated in FIG. 5 can be realized by the network IF 615, for example.
- FIG. 7 is a diagram illustrating an example of a protocol stack in the wireless communication system according to the second embodiment.
- a protocol stack 700 shown in FIG. 7 can be applied to the wireless communication system 200 according to the second embodiment.
- the protocol stack 700 is an LTE-A protocol stack defined in 3GPP.
- Layer groups 701 to 705 are layer groups indicating processes in the UE 211, eNB 221, SGW 231, PGW 232, and external network server, respectively.
- filtering of the IP flow is performed in order to carry out handling according to the QoS class for each IP flow.
- the PGW 232 performs packet filtering on the IP flow and classifies the IP flow into EPS bearers 241 to 24n.
- the PGW 232 For the uplink in which the UE 211 transmits the IP flow, the PGW 232 notifies the UE 211 of the packet filtering rule. Then, based on the filtering rule notified from the PGW 232, the UE 211 performs packet filtering on the IP flow to classify the IP flow into EPS bearers 241 to 24n.
- the PGW 232 performs IP flow filtering by the filter layer 711 (Filter) included in the IP layer (IP) of the layer group 704 of the PGW 232.
- the UE 211 performs IP flow filtering using a filter layer 712 (Filter) included in the IP layer (IP) of the layer group 701 of the UE 211.
- the PGW 232 in the case of downlink or the UE 211 (in the case of uplink) sets a QoS value in the ToS field of the header of the IP packet.
- Packet filtering by the PGW 232 or the UE 211 is performed using, for example, 5-tuple (transmission / reception source IP address, transmission / reception source port number, protocol type).
- the filtering rule for packet filtering is called, for example, TFT (Traffic Flow Template).
- TFT Traffic Flow Template
- IP flow filtering When IP flow filtering is performed using TFT, the IP flow can be classified into 11 types of EPS bearers at maximum.
- One bearer among the EPS bearers 241 to 24n is called a default bearer (Default Bearer).
- the default bearer is generated when the PGW 232 assigns an IP address to the UE 211, and always exists until the IP address assigned to the UE 211 is released.
- a bearer different from the default bearer among the EPS bearers 241 to 24n is referred to as an individual bearer (Dedicated Bearer).
- the individual bearer can be generated and released as appropriate according to the situation of user data to be transmitted.
- FIG. 8 is a diagram of an example of layer 2 in the wireless communication system according to the second embodiment.
- the processing illustrated in FIG. 8 can be applied to the wireless communication system 200 according to the second embodiment.
- the process shown in FIG. 8 is an LTE-A layer 2 process defined in 3GPP.
- Layer 2 of LTE-A includes PDCP 810, RLC 820, and MAC 830.
- PDCP 810 includes ROHC (Robust Header Compression) that performs header compression of incoming IP datagrams and processing related to security.
- the security-related processing includes, for example, confidentiality and integrity protection.
- user data is forwarded to a lower layer (for example, layer 1) after these processes of PDCP 810 are performed.
- the UE 211 when implementing dual connectivity, is capable of simultaneous communication with a maximum of two base stations (eg, eNBs 221 and 222).
- the MCG bearer 801 Master Cell Group Bearer
- the MCG bearer 801 is a radio bearer of the main base station.
- split bearer 802 Split Bearer
- SCG bearer 803 Secondary Cell Group Bearer
- split bearer 802 when user data is forwarded from layer 2 to a lower layer (for example, layer 1), user data is forwarded to only one base station or user data is forwarded to two base stations. It is possible to select.
- RLC 820 includes primary processing before wireless transmission of user data.
- the RLC 820 includes division of user data (Segm .: Segmentation) for adjusting the user data to a size according to the radio quality.
- the RLC 820 may include an ARQ (Automatic Repeat Request) or the like for retransmission of user data that could not be error-corrected in the lower layer.
- ARQ Automatic Repeat Request
- the EPS bearer is mapped to a corresponding logical channel (Logical Channel) and wirelessly transmitted.
- the MAC 830 includes wireless transmission control.
- the MAC 830 includes processing for performing packet scheduling and performing HARQ (Hybrid Automatic Repeat reQuest) of transmission data.
- HARQ is performed for each carrier to be aggregated in carrier aggregation.
- the transmission side adds the LCID (Logical Channel Identifier) to the MAC SDU (MAC Service Data Unit), which is user data, and transmits it.
- the receiving side converts the radio bearer into an EPS bearer using the LCID added by the transmitting side.
- FIG. 9 is a diagram illustrating an example of an IP header of an IP packet transmitted in the wireless communication system according to the second embodiment.
- an IP packet having an IP header 900 shown in FIG. 9 is transmitted.
- the IP header 900 includes, for example, a source address 901 indicating a transmission source and a destination address 902 indicating a destination.
- the IP header 900 includes a ToS field 903 for performing QoS. The above-described QoS control is performed based on the value of the ToS field 903, for example.
- FIG. 10 is a diagram illustrating an example of the value of the ToS field included in the IP header of the IP packet transmitted in the wireless communication system according to the second embodiment.
- eight patterns indicate that the upper pattern has a higher priority (priority).
- IP packet corresponds to network control, and is reserved for control such as routing.
- IP packet corresponds to Internet control, and is reserved for control of routing and the like.
- the QoS priority information is not limited to this, for example, using a DSCP (Differentiated Services Code Point) field. Also good. DSCP is a field corresponding to the first 6 bits in the ToS field 903.
- DSCP is a field corresponding to the first 6 bits in the ToS field 903.
- FIG. 11 is a diagram illustrating an example of aggregation by LTE-A and WLAN in the wireless communication system according to the second embodiment.
- the layer 2 processing in the aggregation by LTE-A and WLAN is based on the dual connectivity processing described above in consideration of backward compatibility of LTE-A, for example.
- the IP flow 1101 is an IP flow between the UE 211 and the eNB 221 using HTTP (Hypertext Transfer Protocol).
- the IP flow 1102 is an IP flow using FTP (File Transfer Protocol) between the UE 211 and the eNB 221.
- On-load processing 1111 indicates processing when IP flows 1101 and 1102 are transmitted by LTE-A without being offloaded to the WLAN.
- This onload processing 1111 corresponds to data transmission using wireless communication by the first wireless communication 101 shown in FIG.
- processing is performed in the order of PDCP, RLC, LTE-MAC, and LTE-PHY for each of the IP flows 1101 and 1102.
- the PDCP, RLC, and LTE-MAC are, for example, PDCP 810, RLC 820, and MAC 830 shown in FIG.
- LTE-PHY is a physical layer in LTE-A.
- the offload processing 1112 indicates processing when the IP flows 1101 and 1102 are offloaded to the WLAN and transmitted. This offload processing 1112 corresponds to data transmission using the wireless communication by the second wireless communication 102 shown in FIG. In the offload processing 1112, PDCP TM,. 11x MAC,. Processing is performed in the order of 11x PHY. . 11x MAC,. 11x PHY is a MAC layer and a PHY layer in WLAN (802.11x), respectively.
- IP flows are classified into bearers and managed as bearers.
- 802.11x of IEEE the Institute of Electrical and Electronics Engineers
- the IP flow is managed as an IP flow instead of a bearer.
- mapping management 1120 it is required to manage the mapping of which bearer belongs to which L2 layer and perform the onload processing 1111 and the offload processing 1112 at high speed.
- the mapping management 1120 is performed by RRC that performs radio control between the UE 211 and the eNB 221, for example.
- the RRC manages radio bearers, thereby performing an onload process 1111 using radio communication based on LTE-A (first radio communication 101) and an offload process 1112 using radio communication based on WLAN (second radio communication 102). Is supported at the radio bearer level.
- the radio communication system 200 sets the PDCP in LTE-A to the transparent mode (TM) in the offload processing 1112 in order to enable support of WLAN QoS in the offload processing 1112. .
- the IP flows 1101 and 1102 are offloaded to the WLAN without processing such as concealment (encryption), header compression, and addition of a sequence number.
- the ToS field included in the offloaded IP flows 1101 and 1102 in the WLAN For example, in the QoS in IEEE 802.11e, the QoS is managed by aggregating IP flows into four types of AC (Access Category) with reference to the ToS field of the IP header. In the wireless communication system 200, it is possible to perform QoS processing based on the ToS field by referring to the ToS field included in the offloaded IP flows 1101 and 1102 in the WLAN.
- the user data transferred to the WLAN is subjected to concealment processing in the WLAN, for example. For this reason, even if the user data is transferred to the WLAN without being concealed by PDCP, it is possible to avoid the user data being transmitted between the eNB 221 and the UE 211 without being concealed.
- AES Advanced Encryption Standard
- TKIP Temporal Key Integrity Protocol
- WEP Wired Equivalent Privacy
- the processing unit that establishes the convergence point (branch point) when performing offloading to the WLAN is not limited to the PDCP processing unit, but may be an RLC or LTE-MAC processing unit.
- the data link layer (layer 2) such as PDCP, RLC, LTE-MAC, etc. can grasp the congestion status of communication in the radio section between the UE 211 and the eNB 221. For this reason, by establishing a convergence point in the data link layer and performing offloading to the WLAN, whether or not execution of offloading to the WLAN is necessary according to the communication congestion state in the wireless section between the UE 211 and the eNB 221 Etc. can be judged.
- FIG. 12 is a diagram illustrating an example of QoS control based on the ToS field in the wireless communication system according to the second embodiment.
- the eNB 221 has a WLAN communication function and transmits an IP packet 1201 from the eNB 221 to the UE 211 will be described.
- the eNB 221 Based on the ToS field in the IP header of the IP packet 1201, the eNB 221 classifies the IP packet 1201 into one of voices 1211, 1214, or AC 1211 to 1214 of voice, video, best effort, or background.
- the eNB 221 can perform AC classification based on the ToS field with reference to the ToS field of the IP packet 1201 even in the WLAN processing.
- the eNB 221 has a WLAN communication function
- the IP packet 1201 is transmitted from the eNB 221 to the UE 211 (downlink)
- FIG. 13 is a diagram illustrating an example of AC classification in the wireless communication system according to the second embodiment.
- the same parts as those shown in FIG. 13 are identical to FIG. 13 and the same parts as those shown in FIG. 13;
- IP packets 1301 and 1302 are HTTP and FTP IP packets, respectively.
- the eNB 221 performs ToS value analysis classification 1310 for classifying the IP packets 1301 and 1302 into one of ACs 1211 to 1214 based on the value of the ToS field included in the IP header.
- the eNB 221 classifies the IP packet 1301 as AC1213 (best effort) and classifies the IP packet 1302 as AC1214 (background). Then, the eNB 221 transmits the IP packets 1301 and 1302 subjected to the ToS value analysis classification 1310 to the UE 211 by WLAN.
- IP packets 1301 and 1302 by PDCP transparent mode
- ToS value analysis classification 1330 declassification
- ToS value analysis classification 1310 classification
- IP packets 1301 and 1302 are transmitted from the eNB 221 to the UE 211 (downlink)
- FIG. 14 is a diagram of an example of offload in the wireless communication system according to the second embodiment.
- the eNB 221 serves as a master eNB and performs offloading to a WLAN in a WLAN independent configuration using a secondary eNB 223 having a function of eNB and WLAN communication (eNB + WLAN).
- the offload to the WLAN is data transmission using the second wireless communication 102 shown in FIG.
- the secondary eNB 223 is a base station that can communicate with the eNB 221 via an inter-base station interface such as an X2 interface and can communicate with the UE 211 via WLAN.
- EPS bearers 1400 to 140n are set between the eNB 221 and the UE 211 to perform communication, and the EPS bearers 1400 to 140n are offloaded to the WLAN.
- EPS bearers 1400 to 140n are downlink bearers from eNB 221 to UE 211.
- FIG. 14 illustrates a case where ten EPS bearers 1400 to 140n are set, the number of EPS bearers to be set is arbitrary.
- the EPS bearers 1400 to 140n are n + 1 EPS bearers each having an EBI (EPS Bearer ID) of 0 to n (n is, for example, 10).
- the sources (src IP) of the EPS bearers 1400 to 140n are both core networks (CN).
- the destinations (dst IP) of the EPS bearers 1400 to 140n are both UE211 (UE).
- the eNB 221 When the eNB 221 offloads the EPS bearers 1400 to 140n to the WLAN, the eNB 221 transfers the EPS bearers 1400 to 140n to the secondary eNB 223 via the PDCP layers 1410 to 141n, respectively. That is, the eNB 221 controls the offloading of the EPS bearers 1400 to 140n to the WLAN by the layer 2 of LTE-A (PDCP in the example illustrated in FIG. 14).
- LTE-A PDCP in the example illustrated in FIG. 14
- the eNB 221 sets the PDCP layers 1410 to 141n to the transparent mode (PDCP TM) so that the EPS bearers 1400 to 140n are not subjected to processing such as PDCP concealment or header compression.
- the EPS bearers 1400 to 140n are offloaded to the secondary eNB 223 with the PDCP SDU (PDCP Service Data Unit) being maintained.
- the EPS bearers 1400 to 140n are offloaded to the WLAN with the ToS field (QoS information) described above being transparent, that is, processing such as concealment and header compression for the IP header including the ToS field is not performed.
- PDCP SDU is data equivalent to an IP datagram.
- the transfer of the EPS bearers 1400 to 140n from the eNB 221 to the secondary eNB 223 can be performed, for example, in the same manner as the LTE-A handover.
- the transfer of the EPS bearers 1400 to 140n from the eNB 221 to the secondary eNB 223 can be performed using the GTP tunnels 1420 to 142n between the eNB 221 and the secondary eNB 223.
- the GTP tunnels 1420 to 142n are GTP tunnels set for each EPS bearer between the eNB 221 and the secondary eNB 223.
- Secondary eNB 223 receives EPS bearers 1400 to 140n transferred from eNB 221 via GTP tunnels 1420 to 142n by PDCP layers 1430 to 143n, respectively. Then, the secondary eNB 223 performs AC classification 1440 based on the ToS field included in the IP header of the PDCP SDU for each PDCP SDU corresponding to the received EPS bearers 1400 to 140n.
- AC classification 1440 is processing by the function of WLAN (802.11e) in the secondary eNB 223. According to AC classification 1440, for example, as shown in FIG. 12, each PDCP SDU is classified into one of voice (VO), video (VI), best effort (BE), and background (BK) AC. .
- Secondary eNB 223 transmits each PDCP SDU classified by AC classification 1440 to UE 211 via WLAN 1450.
- an SSID Service Set Identifier: service set identifier
- an SSID in the WLAN 1450 can be set to “offload”, for example.
- the UE 211 performs AC declassification 1460 based on the ToS field included in the IP header of the PDCP SDU for each PDCP SDU received via the WLAN 1450.
- the AC declassification 1460 is a process based on the WLAN (802.11e) function in the UE 211.
- the UE 211 reclassifies each PDCP SDU received by the AC declassification 1460 into EPS bearers 1400 to 140n based on the classified AC.
- the UE 211 then processes and receives the reclassified EPS bearers 1400 to 140n by the PDCP layers 1470 to 147n, respectively.
- the PDCP layers 1410 to 141n in the eNB 221 are in a transparent mode, and PDCP concealment and header compression are not performed on the EPS bearers 1400 to 140n. Therefore, the UE 211 sets the PDCP layers 1470 to 147n in the UE 211 to the transparent mode (PDCP TM), so that processing such as decryption for concealment and header decompression for header compression is not performed.
- PDCP TM transparent mode
- the PDCP layers 1410 to 141n of the eNB 221 can be set to the transparent mode. Accordingly, the ToS field included in the IP header of each PDCP SDU can be referred to in the secondary eNB 223 as the offload destination. Therefore, when the EPS bearers 1400 to 140n are offloaded to the WLAN 1450, AC classification 1440 based on the ToS field can be performed to perform QoS control according to the nature of the traffic.
- the EPS bearer when the VoLTE EPS bearer is offloaded to the WLAN 1450, the EPS bearer is classified as a voice (VO) and preferentially transmitted by the WLAN 1450, thereby improving the communication quality of VoLTE.
- VO voice
- the VLAN tag is a VLAN identifier.
- the eNB 221 becomes the master eNB and performs offload to the WLAN in the WLAN independent configuration using the eNB and the secondary eNB 223 having the WLAN communication function (eNB + WLAN).
- the offload to the WLAN is not limited to this, and for example, the eNB 221 may perform offload to the WLAN in a configuration in which the eNB 221 also has a WLAN communication function (eNB + WLAN). In this case, the eNB 221 also performs communication with the UE 211 by WLAN, and the secondary eNB 223 may not be used.
- the secondary eNB 223 may not be used.
- the eNB 221 sets the PDCP layers 1410 to 141n to a non-transparent mode in which PDCP processing such as concealment is performed. Then, the eNB 221 processes the EPS bearers 1400 to 140n processed by the PDCP layers 1410 to 141n in the non-transparent mode in order of RLC, MAC, and PHY, and wirelessly transmits them to the UE 211 by LTE-A.
- the UE 211 receives the EPS bearers 1400 to 140n transmitted from the eNB 221 by LTE-A by processing them using PHY, MAC, RLC, and PDCP (PDCP layers 1470 to 147n). In this case, the UE 211 sets the PDCP layers 1470 to 147n to a non-transparent mode in which PDCP processing such as decoding corresponding to concealment is performed.
- FIG. 15 is a diagram illustrating an example of mapping of QoS classes to AC applicable to the wireless communication system according to the second embodiment.
- the WLAN transmission side (for example, the secondary eNB 223) classifies the EPS bearer to be transmitted as AC, for example, as in a table 1500 in FIG.
- the QoS class of the EPS bearer is identified by QCI (QoS Class Identifier).
- Each QCI is classified into four ACs: voice (VO), video (VI), best effort (BE), and background (BK).
- the WLAN receiving side (for example, UE 211) performs conversion from AC to QoS class.
- the eNB 221 sets an EPS bearer to be offloaded to the UE 211 in advance.
- the UE 211 can identify the EPS bearer based on the EPS bearer set from the eNB 221.
- the UE 211 can perform AC classification based on the EPS bearer set from the eNB 221.
- FIG. 16 is a flowchart of an example of processing performed by the transmission side device in the wireless communication system according to the second embodiment.
- the case of the downlink which transmits user data from eNB 221 to UE211 is demonstrated.
- the eNB 221 determines whether or not to perform offload to the WLAN for user data to the UE 211 (step S1601).
- the determination method in step S1601 will be described later.
- step S1601 when it is determined not to perform offloading (step S1601: No), the eNB 221 sets its own PDCP layer to the non-transparent mode (step S1602).
- the non-transparent mode is a normal mode of the PDCP layer that performs processing such as concealment of PDCP and header compression on user data.
- the eNB 221 may control the UE 211 so that the PDCP layer of the UE 211 is also set to the non-transparent mode in accordance with the PDCP layer of the local station.
- the eNB 221 transmits user data to the UE 211 by LTE-A (step S1603), and ends a series of processes. Since the PDCP layer of the eNB 221 is set to the non-transparent mode in step S1602, in step S1603, user data subjected to PDCP concealment and header compression is transmitted. On the other hand, the UE 211 can receive user data transmitted from the eNB 221 by performing processing such as decryption for concealment and header decompression for header compression in the PDCP layer.
- step S1601 If it is determined in step S1601 that offloading is to be performed (step S1601: Yes), the eNB 221 sets its own PDCP layer to the transparent mode (step S1604). In step S1604, the eNB 221 may control the UE 211 so that the PDCP layer of the UE 211 is also set in the transparent mode in accordance with the PDCP layer of the local station.
- the eNB 221 transmits user data to the UE 211 via the WLAN (step S1605), and ends a series of processes. For example, when the eNB 221 has a WLAN communication function, the eNB 221 transmits user data to the UE 211 by the local station's WLAN communication function. On the other hand, when the eNB 221 does not have the WLAN communication function, the eNB 221 transfers the user data to the UE 211 to the secondary eNB 223 having the WLAN communication function connected to the own station, thereby causing the user data to the UE 211 to be transmitted. Send.
- step S1604 since the PDCP layer of the eNB 221 is set to the transparent mode in step S1604, user data is transmitted in step S1605 without performing PDCP concealment or header compression. This enables QoS control based on the ToS field in WLAN.
- the determination in step S1601 described above can be made based on, for example, whether the UE 211 or the network side (eg, PGW 232) has instructed the user data of the UE 211 to be offloaded to the WLAN. Or judgment of Step S1601 can be performed based on whether the amount of user data to UE211 exceeded a threshold, for example.
- the amount of user data may be the amount per time or the total amount of a series of user data of the UE 211.
- the determination in step S1601 can be performed based on, for example, the delay time of communication between the eNB 221 and the UE 211 by LTE-A, the delay time of communication between the eNB 221 and the UE 211 by WLAN, and the like.
- step S1605 differs depending on whether or not the eNB 221 has a WLAN communication function.
- the UE 211 directly transmits user data to the eNB 221 to the eNB 221.
- the UE 211 transfers the user data to the eNB 221 by transferring the user data to the eNB 221 to the secondary eNB 223 having the WLAN communication function connected to the eNB 221. Send.
- FIG. 17 is a diagram illustrating an example in which a plurality of EPS bearers have the same QoS class in the wireless communication system according to the second embodiment. 17, parts that are the same as the parts shown in FIG. 13 are given the same reference numerals, and descriptions thereof will be omitted. For example, when the IP packets 1301 and 1302 are both background IP packets, in the ToS value analysis classification 1310, the IP packets 1301 and 1302 are both classified as AC1214 (background).
- the receiving side may not be able to uniquely identify the EPS bearer. That is, the receiving side may not be able to convert the received radio bearer into an EPS bearer.
- the IP flow between the eNB 221 and the PGW 232 is managed as an EPS bearer, when the eNB 221 cannot convert the radio bearer into the EPS bearer, it becomes difficult to transmit the IP flow from the eNB 221 to the PGW 232.
- the transmission side of the UE 211 and the eNB 221 is configured not to simultaneously offload EPS bearers having the same QoS class.
- the transmitting side when transmitting a plurality of EPS bearers having the same QoS class to the UE 211, the transmitting side offloads only one of the plurality of EPS bearers to the WLAN, and the remaining EPS bearers are off to the WLAN. Transmit to UE 211 without loading.
- the transmission side when transmitting a plurality of EPS bearers having the same QoS class to the UE 211, the transmission side performs transmission by LTE-A without performing offloading to the WLAN.
- the UE 211 can uniquely identify the EPS bearer based on the AC for each user data offloaded to the WLAN.
- the transmitting side of the UE 211 and the eNB 221 may perform a process of aggregating the plurality of EPS bearers into one bearer.
- a process of aggregating a plurality of EPS bearers into one bearer for example, “UE requested bearer resource modification procedure” defined in TS23.401 of 3GPP can be used.
- the UE 211 can uniquely identify the EPS bearer based on the AC for each user data offloaded to the WLAN.
- the transmitting-side station of eNB 221 and UE 211 transmits LTE-A when transmitting user data using WLAN under the control of RRC that controls LTE-A.
- the QoS information is made transparent in PDCP, which is the processing unit.
- the transmitting station of the eNB 221 and the UE 211 can perform QoS control according to the QoS information in the transmission process of user data in the WLAN. For this reason, it is possible to suppress a decrease in communication quality due to transmission of user data using offload to the WLAN, or to maintain the communication quality.
- Embodiment 3 In the third embodiment, a method is described in which the restriction of not simultaneously offloading EPS bearers having the same QoS class is eliminated, and the amount of user data that can be offloaded can be increased. It should be noted that the third embodiment can be understood as a concrete example of the above-described first embodiment, and can of course be implemented in combination with the first embodiment. Needless to say, Embodiment 3 can also be implemented in combination with portions common to Embodiment 2.
- FIG. 18 is a diagram illustrating an example of a method of identifying an EPS bearer using a UL TFT in the wireless communication system according to the third embodiment. 18, parts that are the same as the parts shown in FIG. 14 are given the same reference numerals, and descriptions thereof will be omitted.
- FIG. 18 illustrates a case where the eNB 221 performs an offload to a WLAN in a configuration in which the eNB 221 has a WLAN communication function (eNB + WLAN).
- EPS bearers 1400 to 140n are uplink bearers from UE 211 to eNB 221. That is, the source (src IP) of the EPS bearers 1400 to 140n is the UE 211 (UE).
- the destinations (dst IP) of the EPS bearers 1400 to 140n are both the core network (CN).
- the UE 211 causes the EPS bearers 1400 to 140n to pass through the PDCP layers 1470 to 147n when offloading the EPS bearers 1400 to 140n to the WLAN. At this time, the UE 211 does not perform processing such as concealment and header compression on the EPS bearers 1400 to 140n by the PDCP layers 1470 to 147n by setting the PDCP layers 1470 to 147n to the transparent mode (PDCP TM). To. As a result, the EPS bearers 1400 to 140n via the PDCP layers 1470 to 147n remain in the PDCP SDU state.
- the UE 211 performs AC classification 1810 based on the ToS field included in the IP header of the PDCP SDU for each PDCP SDU corresponding to the EPS bearers 1400 to 140n via the PDCP layers 1470 to 147n.
- the AC classification 1810 is a process based on the WLAN (802.11e) function in the UE 211.
- Each PDCP SDU classified by the AC classification 1810 is transmitted to the eNB 221 via the WLAN 1450.
- the eNB 221 performs AC declassification 1820 on each PDCP SDU received via the WLAN 1450 based on the ToS field included in the IP header of the PDCP SDU.
- the AC declassification 1820 is a process based on a WLAN (802.11e) function in the eNB 221.
- the eNB 221 performs packet filtering 1830 based on UL (uplink) TFTs for each PDCP SDU received by the AC declassification 1820.
- packet filtering 1830 each PDCP SDU is filtered according to whether each condition (f1 to f3) corresponding to the TFT is satisfied (match / no).
- EPS bearer classification 1831 for identifying the EPS bearer is performed according to the filtering result. Thereby, the EPS bearer corresponding to each offloaded PDCP SDU is identified.
- a method for acquiring a UL TFT in the eNB 221 will be described later (see, for example, FIG. 20).
- the eNB 221 transfers each PDCP SDU to the PDCP layer corresponding to the EPS bearer of the PDCP SDU among the PDCP layers 1410 to 141n based on the identification result by the EPS bearer classification 1831. Thereby, each PDCP SDU (IP flow) offloaded by the WLAN is converted into a corresponding EPS bearer and transferred to the PDCP layers 1410 to 141n.
- PDCP layers 1410 to 141n terminate each EPS bearer offloaded by the WLAN.
- the PDCP layers 1470 to 147n in the UE 211 are in the transparent mode, and processing such as PDCP concealment and header compression is not performed on the EPS bearers 1400 to 140n.
- the eNB 221 sets the PDCP layers 1410 to 141n in the eNB 221 to the transparent mode (PDCP TM) so that processing such as decryption for concealment and header decompression for header compression is not performed.
- the EPS bearer terminated by the PDCP layers 1410 to 141n is transmitted to the PGW 232 via the SGW 231.
- the eNB 221 can identify the EPS bearer of each offloaded PDCP SDU by performing packet filtering 1830 based on the UL TFT for each offloaded PDCP SDU. For this reason, the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the UE 211 sets the PDCP layers 1470 to 147n to a non-transparent mode in which PDCP processing such as concealment is performed. Then, the UE 211 processes the EPS bearers 1400 to 140n processed by the PDCP layers 1470 to 147n in the non-transparent mode in order of RLC, MAC, and PHY, and wirelessly transmits them to the eNB 221 by LTE-A.
- the eNB 221 receives the EPS bearers 1400 to 140n transmitted from the UE 211 by LTE-A by processing the PHY, MAC, RLC, and PDCP (PDCP layers 1410 to 141n). In this case, the eNB 221 sets the PDCP layers 1410 to 141n to a non-transparent mode in which PDCP processing such as decoding corresponding to concealment is performed.
- FIG. 19 is a diagram illustrating another example of a method for identifying an EPS bearer using a UL TFT in the wireless communication system according to the third embodiment. 19, parts that are the same as the parts shown in FIG. 14 or 18 are given the same reference numerals, and descriptions thereof will be omitted.
- an eNB 221 becomes a master eNB and performs offload to a WLAN in a WLAN independent configuration using a secondary eNB 223 having a function of eNB and WLAN communication.
- GTP tunnels 1420 to 142n for each EPS bearer are set between the eNB 221 and the secondary eNB 223.
- Secondary eNB 223 receives each PDCP SDU transmitted from UE 211 via WLAN 1450. Then, the secondary eNB 223 performs AC declassification 1820 and packet filtering 1830 similar to the example illustrated in FIG. 18 on each received PDCP SDU. Thereby, EPS bearer classification 1831 in the packet filtering 1830 is performed for each PDCP SDU, and the EPS bearer corresponding to each PDCP SDU is identified.
- the secondary eNB 223 transfers each PDCP SDU to the GTP tunnel corresponding to the EPS bearer of the PDCP SDU among the GTP tunnels 1420 to 142n based on the identification result by the EPS bearer classification 1831. Accordingly, each PDCP SDU is transferred to the corresponding PDCP layer among the PDCP layers 1410 to 141n of the eNB 221.
- the secondary eNB 223 can identify the EPS bearer of each offloaded PDCP SDU by performing packet filtering 1830 based on the UL TFT for each offloaded PDCP SDU. Then, the secondary eNB 223 transfers each PDCP SDU through the GTP tunnels 1420 to 142n according to the identification result of the EPS bearer, whereby the eNB 221 can receive each offloaded PDCP SDU as an EPS bearer.
- the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- FIG. 20 is a diagram illustrating an example of a TFT acquisition method in the wireless communication system according to the third embodiment.
- Each step shown in FIG. 20 is a process of “Dedicated Bearer Activation Procedure” defined in 3GPP TS23.401.
- a PCRF 2001 (Policy and Charging Rules Function) shown in FIG. 20 is a processing unit connected to the packet core network 230 for setting priority control and charging rules according to services.
- the PGW 232 sets the UL and DL TFTs for the UE 211, stores the set TFTs in the create bearer request 2002 shown in FIG. 20, and transmits them to the SGW 231.
- the SGW 231 transmits the create bearer request 2002 transmitted from the PGW 232 to the MME 233.
- the MME 233 transmits a bearer setup request / session management request 2003 including a TFT included in the create bearer request 2002 transmitted from the SGW 231 to the eNB 221.
- the TFT is included in the session management request in the bearer setup request / session management request 2003, for example.
- eNB221 can acquire TFT of UL and DL.
- ENB 221 transmits RRC connection reconfiguration 2004 including a TFT of UL among TFTs included in bearer setup request / session management request 2003 transmitted from MME 233 to UE 211. Thereby, UE211 can acquire UL TFT.
- the UL TFT can be specified in the RRC connection reconfiguration message, but is preferably specified in a NAS (Non Access Stratum) PDU transmitted in the message. The same applies thereafter.
- the eNB 221 can perform the packet filtering 1830 using the UL TFT acquired from the bearer setup request / session management request 2003.
- the eNB 221 transmits the UL TFT acquired from the bearer setup request / session management request 2003 to the secondary eNB 223.
- the secondary eNB 223 can perform packet filtering 1830 based on the UL TFT transmitted from the eNB 221.
- FIG. 21 is a diagram illustrating an example of a method of identifying an EPS bearer using DL TFTs in the wireless communication system according to the third embodiment.
- parts that are the same as the parts shown in FIG. 14 are given the same reference numerals, and descriptions thereof will be omitted.
- FIG. 21 illustrates a case where the eNB 221 performs an offload to a WLAN in a configuration in which the eNB 221 has a WLAN communication function (eNB + WLAN).
- EPS bearers 1400 to 140n are downlink bearers from eNB 221 to UE 211.
- the UE 211 performs packet filtering 2110 based on DL (downlink) TFTs on each PDCP SDU received by the AC declassification 1460. Since the packet filtering 2110 by the UE 211 is a process based on the DL TFT, for example, it is the same process as the packet filtering by the filter layer 711 in the PGW 232 shown in FIG.
- each PDCP SDU is filtered according to whether each condition (f1 to f3) corresponding to the TFT is satisfied (match / no). Then, EPS bearer classification 2111 for identifying the EPS bearer according to the result of this filtering is performed. Thereby, the EPS bearer corresponding to each offloaded PDCP SDU is identified.
- the eNB 221 stores the DL TFT in addition to the UL TFT in the RRC connection reconfiguration 2004 to the UE 211 shown in FIG. Accordingly, the UE 211 can acquire the DL TFT from the RRC connection reconfiguration 2004, and can perform packet filtering 2110 based on the acquired DL TFT.
- the UE 211 transfers each PDCP SDU to the PDCP layer corresponding to the EPS bearer of the PDCP SDU among the PDCP layers 1470 to 147n based on the identification result by the EPS bearer classification 2111. Accordingly, each PDCP SDU (IP flow) offloaded by the WLAN is converted into a corresponding EPS bearer and transferred to the PDCP layers 1470 to 147n.
- the UE 211 can identify the EPS bearer of each offloaded PDCP SDU by performing packet filtering 2110 based on the DL TFT for each offloaded PDCP SDU. For this reason, the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- FIG. 22 is a diagram illustrating another example of a method of identifying an EPS bearer using DL TFTs in the wireless communication system according to the third embodiment.
- downlink eNB 221 becomes a master eNB and performs offload to WLAN in a WLAN independent configuration using secondary eNB 223 having a function of eNB and WLAN communication.
- GTP tunnels 1420 to 142n for each EPS bearer are set between the eNB 221 and the secondary eNB 223.
- Secondary eNB 223 receives each PDCP SDU transmitted from UE 211 via WLAN 1450. Then, the secondary eNB 223 transfers each received PDCP SDU to the PDCP layers 1430 to 143n.
- the UE 211 performs packet filtering 2110 based on the DL TFT on each offloaded PDCP SDU, so that the EPS bearer of each offloaded PDCP SDU is obtained. Can be identified. For this reason, the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the number of EPS bearers that can be offloaded is not limited by the number of bits of the VLAN tag, for example, as in the case of using a VLAN tag, and the EPS bearer can be identified. It is. Further, according to the method using TFTs shown in FIGS. 18 to 22, the EPS bearer can be identified without adding a header such as a VLAN tag to the offloaded user data.
- FIG. 23 is a diagram illustrating an example of a method for identifying an EPS bearer using a virtual IP flow in the wireless communication system according to the third embodiment.
- the same parts as those shown in FIG. 23 are identical parts as those shown in FIG. 23.
- FIG. 23 illustrates a case where the eNB 221 performs an offload to a WLAN in a configuration in which the eNB 221 has a WLAN communication function (eNB + WLAN).
- EPS bearers 1400 to 140n are downlink bearers from eNB 221 to UE 211.
- a virtual GW 2310 is set between the PDCP layers 1410 to 141n and the WLAN 1450 in the eNB 221.
- the virtual GW 2310 includes NAT processing units 2320 to 232n and a MAC processing unit 2330 (802.3 MAC).
- a virtual GW 2340 is set between the WLAN 1450 and the PDCP layers 1470 to 147n in the UE 211.
- the virtual GW 2340 includes a MAC processing unit 2350 (802.3 MAC) and de-NAT processing units 2360 to 236n.
- the EPS bearers 1400 to 140n passing through the PDCP layers 1410 to 141n in the transparent mode are transferred to the NAT processing units 2320 to 232n of the virtual GW 2310.
- the NAT processing units 2320 to 232n perform NAT (Network Address Translation) processing for classifying the EPS bearers 1400 to 140n into virtual IP flows according to virtual destination IP addresses, respectively.
- the virtual IP flow is a local virtual data flow between the eNB 221 and the UE 211, for example.
- the virtual destination IP address is a destination address of the virtual IP flow.
- the NAT processing units 2320 to 232n transfer the classified virtual IP flows to the MAC processing unit 2330.
- the NAT processing units 2320 to 232n map the EPS bearers 1400 to 140n and the virtual destination IP address on a one-to-one basis.
- the virtual source IP address (src IP) of each virtual IP flow transferred from the NAT processing units 2320 to 232n can be, for example, the virtual GW 2310 (vGW).
- the virtual destination IP address (dst IP) of each virtual IP flow transferred from the NAT processing units 2320 to 232n may be C-RNTI + 0 to C-RNTI + 10, respectively.
- the C-RNTI Cell-Radio Network Temporary Identifier: cell radio network temporary identifier
- C-RNTI Cell-Radio Network Temporary Identifier: cell radio network temporary identifier
- C-RNTI has a 16-bit value.
- a class A IP address is used, about 24 bits of EPS bearers that are sufficient for offloading can be identified.
- the method of generating the virtual source IP address is not limited to this.
- the MAC processing unit 2330 converts each virtual IP flow transferred from the NAT processing units 2320 to 232n into a MAC frame such as Ethernet or IEEE 802.3.
- Ethernet is a registered trademark.
- the source MAC address (src MAC) of the MAC frame can be any private address (any private) in the virtual GWs 2310 and 2340, for example.
- the source MAC address of the MAC frame can be an address (x is an arbitrary value) with the first octet as “xxxxxxxx10”.
- the destination MAC address (dst MAC) of the MAC frame can be the MAC address (UE MAC) of the UE 211, for example.
- the eNB 221 performs AC classification 1440 on the MAC frame converted by the MAC processing unit 2330, and transmits the MAC frame subjected to AC classification 1440 to the UE 211 via the WLAN 1450.
- the UE 211 performs AC declassification 1460 on the MAC frame received from eNB 221 via WLAN 1450.
- the MAC processing unit 2350 of the virtual GW 2340 receives the MAC frame subjected to the AC declassification 1460 as a virtual IP flow.
- the de-NAT processing units 2360 to 236n convert the virtual IP flow into the EPS bearer by referring to the virtual destination IP address (dst IP) of the virtual IP flow for the virtual IP flow received by the MAC processing unit 2350. . At this time, the virtual destination IP address of the virtual IP flow is converted to the original IP address by de-NAT by the de-NAT processing units 2360 to 236n.
- the virtual GWs 2310 and 2340 can identify the EPS bearer as a virtual IP flow.
- the IP address and the MAC address can be composed of private space addresses.
- the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the downlink has been described, but the EPS bearer can be identified by the same method for the uplink. That is, by constructing a virtual IP network between the virtual GWs 2310 and 2340 set in the eNB 221 and the UE 211, the EPS bearer of each PDCP SDU that is offloaded in the uplink can be identified.
- FIG. 24 is a diagram illustrating another example of a method for identifying an EPS bearer using a virtual IP flow in the wireless communication system according to the third embodiment.
- downlink eNB 221 becomes a master eNB and performs offload to WLAN in a WLAN independent configuration using secondary eNB 223 having a function of eNB and WLAN communication.
- GTP tunnels 1420 to 142n for each EPS bearer are set between the eNB 221 and the secondary eNB 223.
- the NAT processing units 2320 to 232n shown in FIG. 23 are set to the secondary eNB 223 in the example shown in FIG.
- the secondary eNB 223 receives each PDCP SDU transmitted from the UE 211 via the WLAN 1450. Then, the secondary eNB 223 transfers each received PDCP SDU to the NAT processing units 2320 to 232n of the virtual GW 2310.
- the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the downlink has been described, but the EPS bearer can be identified by the same method for the uplink. That is, by constructing a virtual IP network between the virtual GWs 2310 and 2340 set in the secondary eNB 223 and the UE 211, the EPS bearer of each PDCP SDU that is offloaded in the uplink can be identified.
- the number of EPS bearers that can be offloaded is not limited to the number of bits of the VLAN tag, for example, when a VLAN tag is used. Be identifiable.
- the eNB 221 and the secondary eNB 223 can be connected not only by the GTP tunnel but also by Ethernet or the like.
- the EPS bearer can be identified without setting a DL TFT in the UE 211 or a UL TFT in the eNB 221. It is. Further, according to the method using the virtual IP flow shown in FIGS. 23 and 24, the EPS bearer can be identified without adding a header such as a VLAN tag to the offloaded user data.
- FIG. 25 is a diagram illustrating an example of a method for identifying an EPS bearer using a VLAN in the wireless communication system according to the third embodiment.
- FIG. 25 the same parts as those shown in FIG. 14 or FIG.
- FIG. 23 a method for identifying an EPS bearer by constructing a virtual IP network has been described.
- FIG. 25 a method for identifying an EPS bearer by a VLAN that virtualizes Ethernet will be described.
- the eNB 221 performs an offload to a WLAN in a configuration in which the eNB 221 has a WLAN communication function (eNB + WLAN).
- the EPS bearers 1400 to 140n are downlink bearers from the eNB 221 to the UE 211.
- virtual GWs 2310 and 2340 are set in the eNB 221 and the UE 211, respectively, as in the example shown in FIG.
- the virtual GW 2310 of the eNB 221 includes VLAN processing units 2510 to 251n and MAC processing units 2520 to 252n (802.3 MAC).
- the virtual GW 2340 of the UE 211 includes MAC processing units 2530 to 253n (802.3 MAC) and de-VLAN processing units 2540 to 254n.
- the EPS bearers 1400 to 140n via the PDCP layers 1410 to 141n in the transparent mode are transferred to the VLAN processing units 2510 to 251n of the virtual GW 2310.
- the VLAN processing units 2510 to 251n classify the EPS bearers 1400 to 140n into local IP flows between the eNB 221 and the UE 211 by the VLAN, and transfer the classified IP flows to the MAC processing units 2520 to 252n.
- the VLAN processing units 2510 to 251n map the EPS bearers 1400 to 140n and the VLAN tags on a one-to-one basis.
- the VLAN identifier of each IP flow transferred from the VLAN processing units 2510 to 251n can be 0 to 10, respectively.
- the MAC processing units 2520 to 252n convert the IP flows transferred from the VLAN processing units 2510 to 251n into MAC frames such as Ethernet and IEEE 802.3, respectively.
- the transmission source MAC address (src MAC) of each MAC frame converted by the MAC processing units 2520 to 252n can be an arbitrary private address (any private) in the virtual GWs 2310 and 2340, for example.
- the source MAC address of the MAC frame may be an address (x is an arbitrary value) with the first octet being “xxxxxx10”.
- the destination MAC address (dst MAC) of each MAC frame converted by the MAC processing units 2520 to 252n can be, for example, the MAC address (UE MAC) of the UE 211.
- the VLAN tag (VLAN tag) of each MAC frame converted by the MAC processing units 2520 to 252n can be 0 to 10 corresponding to each EPS bearer, for example.
- a VLAN tag for each EPS bearer is added to each MAC frame.
- the VLAN tag is a 12-bit tag, for example. Therefore, it is possible to construct a maximum of 4094 VLANs between the virtual GWs 2310 and 2340. If each UE including the UE 211 has all EPS bearers, and if all the EPS bearers are offloaded, it is possible to accommodate about 372 UEs in the WLAN. However, since it is unlikely that all EPS bearers are actually used for communication, it is possible to offload a sufficient number of EPS bearers by using VLAN.
- the eNB 221 performs AC classification 1440 on the MAC frame with the VLAN tag converted by the MAC processing units 2520 to 252n. Then, the eNB 221 transmits the MAC frame with the VLAN tag subjected to the AC classification 1440 to the UE 211 via the WLAN 1450.
- the UE 211 performs AC declassification 1460 on the MAC frame with the VLAN tag received from the eNB 221 via the WLAN 1450.
- the MAC processing units 2530 to 253n of the virtual GW 2340 are MAC processing units corresponding to the EPS bearers 1400 to 140n, respectively.
- Each of the MAC processing units 2530 to 253n IP-flows the MAC frame of the corresponding EPS bearer by referring to the VLAN tag attached to the MAC frame for the MAC frame on which AC declassification 1460 has been performed. Receive.
- the de-VLAN processing units 2540 to 254n convert the IP flows received by the MAC processing units 2530 to 253n into EPS bearers 1400 to 140n, respectively.
- the PDCP layers 1470 to 147n process the EPS bearers 1400 to 140n converted by the de-VLAN processing units 2540 to 254n, respectively.
- the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the downlink has been described, but the EPS bearer can be identified by the same method for the uplink. That is, by setting a VLAN for each EPS bearer between the virtual GWs 2310 and 2340 set in the eNB 221 and the UE 211, the EPS bearer of each PDCP SDU that is offloaded in the uplink can be identified.
- FIG. 26 is a diagram illustrating another example of the method for identifying the EPS bearer using the VLAN in the wireless communication system according to the third embodiment.
- FIG. 26 illustrates a case where the eNB 221 becomes a master eNB and performs offloading to a WLAN in a WLAN independent configuration using the secondary eNB 223 having a function of eNB and WLAN communication.
- GTP tunnels 1420 to 142n for each EPS bearer are set between the eNB 221 and the secondary eNB 223.
- the VLAN processing units 2510 to 251n shown in FIG. 25 are set in the secondary eNB 223 in the example shown in FIG.
- the secondary eNB 223 receives each PDCP SDU transmitted from the UE 211 via the WLAN 1450. Then, the secondary eNB 223 transfers each received PDCP SDU to the VLAN processing units 2510 to 251n of the virtual GW 2310.
- the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the EPS bearer can be identified by the same method for the uplink. That is, by setting the VLAN for each EPS bearer between the virtual GWs 2310 and 2340 set in the secondary eNB 223 and the UE 211, the EPS bearer of each PDCP SDU that is offloaded in the uplink can be identified.
- the eNB 221 and the secondary eNB 223 can be connected not only by the GTP tunnel but also by Ethernet or the like.
- the EPS bearer of each PDCP SDU is identified by adding the VLAN tag without processing the packet referring to the IP header in the WLAN. be able to.
- the EPS bearer can be identified without setting a DL TFT in the UE 211 or a UL TFT in the eNB 221.
- FIG. 27 is a diagram illustrating an example of a method of identifying an EPS bearer using GRE tunneling in the wireless communication system according to the third embodiment.
- FIG. 27 illustrates a case where the eNB 221 performs an offload to a WLAN in a configuration in which the eNB 221 has a WLAN communication function (eNB + WLAN).
- EPS bearers 1400 to 140n are bearers in the downlink direction from eNB 221 to UE 211.
- a virtual GW 2310 is set between the PDCP layers 1410 to 141n and the WLAN 1450 in the eNB 221.
- the virtual GW 2310 includes GRE processing units 2710 to 271n and a MAC processing unit 2330 (802.3 MAC).
- a virtual GW 2340 is set between the WLAN 1450 and the PDCP layers 1470 to 147n in the UE 211.
- the virtual GW 2340 includes a MAC processing unit 2350 (802.3 MAC) and de-GRE processing units 2720 to 272n.
- the EPS bearers 1400 to 140n via the PDCP layers 1410 to 141n in the transparent mode are transferred to the GRE processing units 2710 to 271n of the virtual GW 2310.
- the GRE processing units 2710 to 271n classify the EPS bearers 1400 to 140n by using GRE (Generic Routing Encapsulation) tunneling to local IP flows between the eNB 221 and the UE 211, and the MAC processing units Transfer to 2330.
- GRE Generic Routing Encapsulation
- the GRE processing units 2710 to 271n add a GRE header to the PDCP SDU corresponding to the EPS bearers 1400 to 140n, add an IP header, and transfer the IP flow to the MAC processing unit 2330.
- the source IP address (src IP) of each IP flow transferred from the GRE processing units 2710 to 271n can be, for example, a virtual GW 2310 (vGW).
- the destination IP address (dst IP) of each IP flow transferred from the GRE processing units 2710 to 271n can be, for example, C-RNTI + 0 to C-RNTI + 10, respectively.
- the MAC processing unit 2330 converts each IP flow transferred from the GRE processing units 2710 to 271n into an Ethernet (IEEE 802.3) MAC frame, for example, as in the example shown in FIG.
- the eNB 221 performs AC classification 1440 on the MAC frame converted by the MAC processing unit 2330, and transmits the MAC frame subjected to AC classification 1440 to the UE 211 via the WLAN 1450. Accordingly, the eNB 221 can transmit user data through a WLAN GRE tunnel (encapsulated tunnel) set between the eNB 221 and the UE 211.
- a WLAN GRE tunnel encapsulated tunnel
- the UE 211 performs AC declassification 1460 on the MAC frame received from eNB 221 via WLAN 1450.
- the MAC processing unit 2350 of the virtual GW 2340 receives the MAC frame on which the AC declassification 1460 has been performed as an IP flow, for example, as in the example illustrated in FIG.
- the de-GRE processing units 2720 to 272n refer to the destination IP address (dst IP) included in the IP header of the IP flow for the IP flow received by the MAC processing unit 2350, and convert the IP flow into an EPS bearer. To do.
- dst IP destination IP address
- the EPS bearers can be identified as IP flows in the virtual GWs 2310 and 2340.
- the IP address and the MAC address can be composed of private space addresses.
- the downlink has been described, but the EPS bearer can be identified by the same method for the uplink. That is, by constructing a GRE tunnel between the virtual GWs 2310 and 2340, the EPS bearer of each PDCP SDU that is offloaded in the uplink can be identified.
- FIG. 28 is a diagram illustrating another example of a method for identifying an EPS bearer using GRE tunneling in the wireless communication system according to the third embodiment.
- the eNB 221 serves as a master eNB and performs offloading to a WLAN in a WLAN independent configuration using the secondary eNB 223 having a function of eNB and WLAN communication.
- GTP tunnels 1420 to 142n for each EPS bearer are set between the eNB 221 and the secondary eNB 223.
- Secondary eNB 223 receives each PDCP SDU transmitted from UE 211 via WLAN 1450. Then, the secondary eNB 223 transfers each received PDCP SDU to the GRE processing units 2710 to 271n.
- the UE 211 can identify the EPS bearer of each offloaded PDCP SDU by using GRE tunneling. For this reason, the wireless communication system 200 enables offloading to the WLAN without the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN, and increases the amount of user data that can be offloaded. Can be achieved.
- the EPS bearer is identified without limiting the number of EPS bearers that can be offloaded to the number of bits of the VLAN tag, for example, when a VLAN tag is used. Is possible.
- the eNB 221 and the secondary eNB 223 can be connected not only by the GTP tunnel but also by Ethernet or the like.
- the EPS bearer can be identified without setting the DL TFT in the UE 211 or the UL TFT in the eNB 221. . Further, according to the method using GRE tunneling shown in FIGS. 27 and 28, the EPS bearer can be identified without adding a header such as a VLAN tag to the offloaded user data.
- the third embodiment it is possible to perform offloading to the WLAN without providing the restriction that the EPS bearer having the same QoS class is not simultaneously offloaded to the WLAN. For this reason, the amount of user data that can be offloaded can be increased.
- user data received as a radio bearer by the UE 211 may be forwarded to a higher layer (for example, an application layer) of the own station without being converted into a bearer.
- a higher layer for example, an application layer
- the UE 211 can perform offload to the WLAN without identifying the bearer.
- the base station As described above, according to the wireless communication system, the base station, and the mobile station, it is possible to suppress a decrease in communication quality or to maintain communication quality.
- VoLTE traffic also becomes best effort, and the communication quality of VoLTE deteriorates.
- the ToS field can be referred to in the WLAN by setting the PDCP of LTE-A in the transparent mode in the offload to the WLAN, and according to the nature of the traffic. QoS control is possible.
- VoLTE traffic is classified into voice (VO) and preferentially transmitted by WLAN, so that the communication quality of VoLTE can be improved.
- 3GPP's LTE-A will also take into account fifth-generation mobile communications, aiming to cope with the increasing mobile traffic and improve user experience, so that system communications can be performed in cooperation with other wireless systems. Consideration is being made. In particular, cooperation with WLANs widely implemented in smart phones as well as homes and companies becomes an issue.
- LAA Liense Assisted Access
- LAA is a carrier aggregation of an unlicensed frequency band and a licensed frequency band for LTE-A, and is a layer 1 technique for controlling radio transmission of the unlicensed frequency band by an LTE-A control channel.
- LTE-A and WLAN are aggregated at Layer 2, and standardization for cellular communication in cooperation with each other is about to start. This is called LTE-WLAN aggregation.
- the LTE-WLAN aggregation has the following advantages compared to the method described above.
- LTE-WLAN aggregation cooperative offloading is possible by connecting an LTE-A base station and an installed WLAN access point at the layer 2 level.
- the process of setting PDCP in the LTE-A side layer 2 to the transparent mode has been described, but other methods are also possible.
- the IP header of the data before the processing such as concealment may be added to the head of the data subjected to the processing such as concealment while performing processing such as concealment for PDCP.
- the WLAN it is possible to perform transmission control based on the QoS information by referring to the QoS information included in the IP header of the data before the process such as concealment.
- Second wireless communication 110, 110A, 110B, 500, 600 Base station 111, 320, 520 Control unit 112, 121 Processing unit 120 Mobile station 201 IP address allocation 211 UE 221 and 222 eNB 221a, 222a cell 223 secondary eNB 230 Packet Core Network 231 SGW 232 PGW 233 MME 241 to 24n, 1400 to 140n EPS bearer 251 to 25n Radio bearer 300,400 Terminal 310,510 Wireless communication unit 311,511 Wireless transmission unit 312,512 Wireless reception unit 330,530 Storage unit 411,611 Antenna 412 612 RF circuit 413 , 613 Processor 414, 614 Memory 540 Communication unit 615 Network IF 700 Protocol stack 701 to 705 Layer group 711, 712 Filter layer 801 MCG bearer 802 Split bearer 803 SCG bearer 810 PDCP 820 RLC 830 MAC 900 IP header 901 Source address 902 Destination address 903 ToS field
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Abstract
Description
図1は、実施の形態1にかかる無線通信システムの一例を示す図である。図1の(a)に示すように、実施の形態1にかかる無線通信システム100は、基地局110と、移動局120と、を含む。無線通信システム100においては、基地局110と移動局120との間で、第1の無線通信101を用いたデータ伝送と、第2の無線通信102を用いたデータ伝送と、が可能である。
図2は、実施の形態2にかかる無線通信システムの一例を示す図である。図2に示すように、実施の形態2にかかる無線通信システム200は、UE211と、eNB221,222と、パケットコア網230と、を含む。無線通信システム200は、たとえば3GPPにおいて規定されたLTE-Aなどの移動体通信システムであるが、無線通信システム200の通信規格はこれらに限らない。
実施の形態3においては、同一のQoSクラスを有するEPSベアラを同時にオフロードしないという制約をなくし、オフロード可能なユーザデータの量の増加を図ることができる方法について説明する。なお、実施の形態3は、上述した実施の形態1を具象化した実施例として捉えることができるため、実施の形態1と組み合わせて実施できることは言うまでもない。また、実施の形態3は、実施の形態2と共通する部分についても組み合わせて実施できることは言うまでもない。
101 第1の無線通信
102 第2の無線通信
110,110A,110B,500,600 基地局
111,320,520 制御部
112,121 処理部
120 移動局
201 IPアドレスアロケーション
211 UE
221,222 eNB
221a,222a セル
223 セカンダリeNB
230 パケットコア網
231 SGW
232 PGW
233 MME
241~24n,1400~140n EPSベアラ
251~25n ラジオベアラ
300,400 端末
310,510 無線通信部
311,511 無線送信部
312,512 無線受信部
330,530 記憶部
411,611 アンテナ
412,612 RF回路
413,613 プロセッサ
414,614 メモリ
540 通信部
615 ネットワークIF
700 プロトコルスタック
701~705 レイヤ群
711,712 フィルタレイヤ
801 MCGベアラ
802 スプリットベアラ
803 SCGベアラ
810 PDCP
820 RLC
830 MAC
900 IPヘッダ
901 ソースアドレス
902 デスティネーションアドレス
903 ToSフィールド
1000,1500 テーブル
1101,1102 IPフロー
1111 オンロード処理
1112 オフロード処理
1120,1320 マッピング管理
1201,1301,1302 IPパケット
1211~1214 AC
1310,1330 ToS値解析分類
1410~141n,1430~143n,1470~147n PDCPレイヤ
1420~142n GTPトンネル
1440,1810 ACクラシフィケーション
1450 WLAN
1460,1820 ACデクラシフィケーション
1830,2110 パケットフィルタリング
1831,2111 EPSベアラクラシフィケーション
2001 PCRF
2002 クリエイトベアラリクエスト
2003 ベアラセットアップリクエスト/セッションマネジメントリクエスト
2004 RRCコネクションリコンフィギュレーション
2310,2340 仮想GW
2320~232n NAT処理部
2330,2350,2520~252n,2530~253n MAC処理部
2360~236n de-NAT処理部
2510~251n VLAN処理部
2540~254n de-VLAN処理部
2710~271n GRE処理部
2720~272n de-GRE処理部
Claims (14)
- 第1の無線通信を制御する制御部により前記第1の無線通信と異なる第2の無線通信を制御する基地局と、
前記第1の無線通信または前記第2の無線通信を用いて前記基地局との間でデータ伝送が可能な移動局と、
を含み、前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、前記基地局および前記移動局のうちの送信側の局における前記第1の無線通信を行うための処理部は、前記第1の無線通信を行うための収束点を確立し、前記収束点において、前記データに含まれるサービス品質情報を透過にして、前記基地局および前記移動局のうちの受信側の局へ前記データを伝送する、
ことを特徴とする無線通信システム。 - 前記送信側の局における前記第1の無線通信を行うための処理部は、
前記基地局と前記移動局との間で前記第2の無線通信を用いずに前記第1の無線通信を用いてデータを伝送する際に、前記データに対して、秘匿化、ヘッダ圧縮およびシーケンス番号の付加の少なくともいずれかを含む処理を行い、
前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、前記データに対して、前記秘匿化、ヘッダ圧縮およびシーケンス番号の付加の少なくともいずれかを含む処理を行わない、
ことを特徴とする請求項1に記載の無線通信システム。 - 前記送信側の局における前記第1の無線通信を行うための処理部は、前記収束点において、前記基地局と前記移動局との間の複数のベアラを集約し、集約したベアラによって前記受信側の局へ前記データを伝送することを特徴とする請求項1に記載の無線通信システム。
- 前記制御部は、前記基地局と前記移動局との間の複数のベアラであって、前記サービス品質情報が示すサービスクラスが同一である複数のベアラの各データを前記第2の無線通信を用いて同時に伝送しないように、前記受信側の局への前記データの伝送を制御することを特徴とする請求項1または2に記載の無線通信システム。
- 前記基地局から前記移動局へ前記第2の無線通信を用いてデータを伝送する際に、前記移動局は、前記第2の無線通信を用いて受信したデータを、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの前記データに対応するベアラを識別せずに処理することを特徴とする請求項1~4のいずれか一つに記載の無線通信システム。
- 前記移動局から前記基地局へ前記第2の無線通信を用いてデータを伝送する際に、前記基地局は、前記第2の無線通信を用いて受信したデータに対して、前記移動局から前記基地局への上りリンクにおけるフィルタリング規則を用いたパケットフィルタリングを行うことによって、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの前記受信したデータに対応するベアラを識別することを特徴とする請求項1~5のいずれか一つに記載の無線通信システム。
- 前記基地局から前記移動局へ前記第2の無線通信を用いてデータを伝送する際に、前記移動局は、前記第2の無線通信を用いて受信したデータに対して、前記基地局から前記移動局への下りリンクにおけるフィルタリング規則を用いたパケットフィルタリングを行うことによって、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの前記受信したデータに対応するベアラを識別することを特徴とする請求項1~6のいずれか一つに記載の無線通信システム。
- 前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、
前記送信側の局は、前記基地局と前記移動局との間に設定した前記第2の無線通信の仮想データフローによって前記データを伝送し、
前記受信側の局は、前記データを受信した仮想データフローの宛先アドレスによって、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの受信した前記データに対応するベアラを識別する、
ことを特徴とする請求項1~6のいずれか一つに記載の無線通信システム。 - 前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、
前記送信側の局は、前記基地局と前記移動局との間に設定した前記第2の無線通信の仮想構内通信網によって前記データを伝送し、
前記受信側の局は、前記データを受信した仮想構内通信網の識別子によって、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの受信した前記データに対応するベアラを識別する、
ことを特徴とする請求項1~6のいずれか一つに記載の無線通信システム。 - 前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、
前記送信側の局は、前記基地局と前記移動局との間に設定した前記第2の無線通信のカプセル化トンネルによって前記データを伝送し、
前記受信側の局は、前記データを受信したカプセル化トンネルの宛先アドレスによって、前記基地局と前記移動局との間の前記第1の無線通信のベアラのうちの受信した前記データに対応するベアラを識別する、
ことを特徴とする請求項1~6のいずれか一つに記載の無線通信システム。 - 前記基地局と前記移動局との間で前記第2の無線通信を用いてデータを伝送する際に、前記基地局および前記移動局は、前記第1の無線通信のデータを伝送するための前記第2の無線通信の通信路を前記基地局と前記移動局との間に設定し、設定した通信路によって前記データを伝送することを特徴とする請求項1~10のいずれか一つに記載の無線通信システム。
- 前記第2の無線通信においては、前記サービス品質情報に基づく伝送制御が行われることを特徴とする請求項1~11のいずれか一つに記載の無線通信システム。
- 移動局との間で第1の無線通信または前記第1の無線通信と異なる第2の無線通信を用いてデータ伝送が可能な基地局において、
前記第1の無線通信および前記第2の無線通信を制御する制御部と、
前記第1の無線通信を行うための処理部であって、前記基地局から前記移動局へ前記第2の無線通信を用いてデータを伝送する際に、前記第1の無線通信を行うための収束点を確立し、前記収束点において、前記データに含まれるサービス品質情報を透過にして前記移動局へ前記データを伝送する処理部と、
を備えることを特徴とする基地局。 - 第1の無線通信を制御する制御部により前記第1の無線通信と異なる第2の無線通信を制御する基地局との間で、前記第1の無線通信または前記第2の無線通信を用いてデータ伝送が可能な移動局であって、
前記第1の無線通信を行うための処理部であって、前記移動局から前記基地局へ前記第2の無線通信を用いてデータを伝送する際に、前記第1の無線通信を行うための収束点を確立し、前記収束点において、前記データに含まれるサービス品質情報を透過にして前記基地局へ前記データを伝送する処理部を備える、
ことを特徴とする移動局。
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CA2976880C (en) | 2021-11-30 |
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CN107251644A (zh) | 2017-10-13 |
JPWO2016132561A1 (ja) | 2017-05-25 |
JP6150024B2 (ja) | 2017-06-21 |
MX2017010498A (es) | 2017-11-28 |
KR101973882B1 (ko) | 2019-04-29 |
CA2976880A1 (en) | 2016-08-25 |
RU2667975C1 (ru) | 2018-09-25 |
US20170332422A1 (en) | 2017-11-16 |
EP3261406B1 (en) | 2022-05-25 |
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CN107251644B (zh) | 2022-06-03 |
US10728932B2 (en) | 2020-07-28 |
EP3261406A4 (en) | 2018-01-31 |
BR112017017402A2 (pt) | 2018-04-03 |
KR20170107485A (ko) | 2017-09-25 |
MX360935B (es) | 2018-11-21 |
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