JP6557294B2 - Mobile communication system and data processing apparatus - Google Patents

Description

  The present invention relates to a mobile communication system and a data processing apparatus.

  Conventionally, in a cellular mobile communication system, when a communicating mobile station located in a serving cell moves to another neighboring cell, based on a measurement report of a reception quality index transmitted from the mobile station, the mobile station There is known handover control in which a base station that is connected and communicates is switched to a base station in a neighboring cell to continue communication (for example, see Non-Patent Documents 1 to 3).

  In addition, a data processing device that processes mobile station application data (hereinafter also referred to as “MEC (Mobile Edge Computing) device”) will be installed near the base station, and technology to reduce the delay in transmitting and receiving application data is being studied. (Non-Patent Documents 4 and 5).

3GPP TS 36.300 "Evolved Universal Terrestrial Radio Access (E-UTRA) and Evolved Universal Terrestrial Radio Access Network (E-UTRAN); Overall description; Stage 2; Protocol specification" V9.10.0, Chapter 10 3GPP TS 36.331 "Evolved Universal Terrestrial Radio Access (E-UTRA); Radio Resource Control (RRC); Protocol specification" V9.18.0, Chapter 5.5.4.4 3GPP TS 36.331 "Evolved Universal Terrestrial Radio Access (E-UTRA); Physical layer; Measurements" (Release 13) Milan Patel et al, "Mobile-Edge Computing" Mobile-Edge Computing-Introductory Technical White Paper, Mobile-Edge Computing (MEC) industry initiative, [Online] Sept. 2014, [Search June 13, 2017], Internet <URL: https://portal.etsi.org/portals/0/tbpages/mec/docs/mobile-edge_computing_-_introductory_technical_white_paper_v1%2018-09-14.pdf> Yun Chao Hu, Milan Patel, Dario Sabella, Nurit Sprecher and Valerie Young, "Mobile Edge Computing A key technology towards 5G", First Edition, ETSI White Paper, No. 11, [Online] Sept. 2015, [2017 6 Search on March 13], Internet <URL: http://www.etsi.org/images/files/ETSIWhitePapers/etsi_wp11_mec_a_key_technology_towards_5g.pdf>

  When a mobile station located in a cell of a base station in which the MEC device is located nearby uses a communication service or session involving data processing by the MEC device, the cell of the base station in which the MEC device is located If handover is performed between the MEC devices in each cell, data processing handover processing is also required, which may increase the handover processing time and increase the communication interruption time associated with the handover processing.

A mobile communication system according to an aspect of the present invention is a mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device, wherein the plurality of cells are Processing data transmitted / received by data communication by the wireless communication device located in the cell, inside the cell base station, in the vicinity of the cell base station, or between the cell base station and the core network device The data processing device is a cell in which the plurality of data processing devices are synchronized with each other in data processing state and data storage state.
In the mobile communication system, when a difference between the data processing state and the data storage state of the data processing device occurs, each of the plurality of data processing devices may transmit information on the difference to another data processing device. .
In the mobile communication system, the mobile communication system includes a synchronization server provided between the base station of the cell and the core network device so as to perform synchronization processing between the plurality of data processing devices, and the plurality of data processing devices When a difference between the data processing state and the data storage state of the data processing device occurs, the difference information is transmitted to the synchronization server, and the synchronization server receives the difference information received from the data processing device. You may transmit to another data processor.

A mobile communication system according to another aspect of the present invention is a mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device, wherein each base of each of the plurality of cells A centralized data processing device that processes data transmitted and received by the wireless communication device located in each of the plurality of cells is disposed between the station and the core network device.
A mobile communication system according to still another aspect of the present invention is a mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device, wherein each of the plurality of cells The base station includes an antenna and an overhanging radio apparatus arranged in the cell, and a baseband apparatus connected to the overhanging radio apparatus via an optical interface, and the baseband apparatus of the plurality of cells includes the overhanging radio Centrally arranged between a device and a core network device, and transmitted / received by data communication by the wireless communication device located in each of the plurality of cells via a predetermined interface to the plurality of baseband devices arranged centrally. A centralized data processing device for processing data to be processed is connected.
In the mobile communication system, the centralized data processing device may be arranged at a base that aggregates traffic of base stations of the plurality of cells.
In the mobile communication system, the centralized data processing device may have at least one of a gateway function related to handover control in the core network device and a mobility management control function of the wireless communication device.
Further, in the mobile communication system, the centralized data processing device or the plurality of baseband devices arranged centrally are provided in an intra-region optical network and connected to a core network via an inter-region optical network. Also good.
In the mobile communication system, the mobile radio communication device may be a mobile base station.

A data processing device according to still another aspect of the present invention is provided in a cell base station of a mobile communication system, in the vicinity of the cell base station or between the cell base station and a core network device, A data processing device for processing data transmitted and received by data communication by a wireless communication device located in a cell, wherein data processing of the data processing device is performed between data processing devices of other cells adjacent to the cell The state and the data storage state are synchronized with each other.
In the data processing device, when a difference between the data processing state and the data storage state of the data processing device occurs, information on the difference may be transmitted to another data processing device.
Further, in the data processing device, when a difference between the data processing state and the data storage state of the data processing device occurs, information on the difference is stored in the cell so as to perform synchronization processing with the other data processing device. You may transmit to the synchronous server provided between the base station and the core network apparatus.

A data processing apparatus according to still another aspect of the present invention is a data processing apparatus that processes data transmitted and received by data communication by a mobile radio communication apparatus located in a cell of a mobile communication system. Data transmitted / received by data communication by the wireless communication device located in each of the plurality of cells may be centrally processed between each base station and the core network device.
A data processing apparatus according to still another aspect of the present invention is a data processing apparatus that processes data transmitted and received by data communication by a mobile radio communication apparatus located in a cell of a mobile communication system. It may be connected via a predetermined interface to a plurality of baseband devices arranged centrally between each overhanging radio device and the core network device.
In the data processing device, the data processing device may be arranged at a base that aggregates traffic of base stations of the plurality of cells.
The data processing device may have at least one of a gateway function related to handover control in the core network device and a mobility management control function of the wireless communication device.
The data processing apparatus may be provided in an intra-region optical line network and connected to a core network through an inter-region optical line network.

  According to the present invention, data communication involving data processing is performed within or near a plurality of cells to which a mobile station is handed over or between a base station of each cell and a core network device. Increase in handover processing time can be suppressed.

Explanatory drawing which shows schematic structure of the mobile communication system which concerns on one Embodiment of this invention. Explanatory drawing which shows schematic structure of the mobile communication system which concerns on other embodiment of this invention. Explanatory drawing which shows schematic structure of the mobile communication system which concerns on further another embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Here, the embodiment of the present invention will be described on the assumption that it is applied to LTE (Long Term Evolution) / LTE-Advanced. However, as long as the system uses a similar cell configuration, the concept of the present invention can be applied to any system. Is also applicable.

FIG. 1 is an explanatory diagram showing a schematic configuration of a mobile communication system according to an embodiment of the present invention.
In FIG. 1, the mobile communication system of the present embodiment is a cellular mobile communication system that complies with the above-mentioned LTE / LTE-Advanced specifications, and an area along a road 200 of a movement route is divided into a plurality of cells 120A (1 ) To 120A (N) are arranged so as to cover continuously, and include a plurality of base stations 120 (1) to 120 (N) (N is a natural number). Each of the base stations 120 (1) to 120 (N) may be a macro cell base station (eNB) or a small cell base station (sNB).

  The base station devices (BSE) 121 (1) to 121 (N) of the base stations 120 (1) to 120 (N) are respectively predetermined interfaces (for example, standard interfaces between base stations defined by LTE). Is connected to a switch (switch) 160A provided in the public optical network 160 through a backhaul line composed of an X2 interface). Each of the base stations 120 (1) to 120 (N) is a mobile station as a mobile wireless communication device mounted on an automobile (passenger car, truck, bus, etc.) 210 that is a moving body traveling on the road 200. 10 can be wirelessly communicated. The public optical network 160 may be a private wide-area optical network or a high-speed network using a high-speed transmission medium other than an optical fiber.

  The mobile station 10 mounted on the automobile 210 is generally called UE (User Equipment) in LTE / LTE-Advanced. When the mobile station 10 is located in the cells 120A (1) to 120A (N) of the base stations 120 (1) to 120 (N), the mobile station 10 corresponds to the base station 120 (1) to 120 (1) to 120A (N). Wireless communication can be performed with 120 (N) using a predetermined communication method and resources.

  In addition, although this embodiment demonstrates the case where the mobile body which mounts the mobile station 10 is the motor vehicle 210, the mobile body in this embodiment is not only the motor vehicle 210 but the railway vehicle, aircraft, or ship which drive | works on a track | line. It may be. The mobile wireless communication device mounted on the automobile 210 forms a mobile cell (hereinafter referred to as “moving cell”) that covers at least the peripheral area outside the automobile 210 and the interior of the automobile 210. It may be a base station. The mobile base station relays communication between a mobile station (user equipment) located in the moving cell and base stations 120 (1) to 120 (N) that are fixed base stations. The moving cell may include a peripheral area outside the automobile 210 and an inner area of the automobile 210. The cell diameter of the moving cell is, for example, 100 m, and may be 20 m or less to 50 m or less.

  Unlike the macro cell base station in a wide area, the above-described small cell base station has a transmission power of 1 W or less, for example, has a wireless communication range of about several meters to several hundred meters (for example, about several tens of meters), It is a small-capacity base station that can be installed indoors such as in stores and offices. Since the small cell base station is provided so as to cover an area smaller than the area covered by the wide-area macro cell base station in the mobile communication network, it is called “Femto base station”, “Home e-Node B”, It may be called “Home eNB”. The small cell base station is connected to the core network 140 of the mobile communication network via a line termination device and a communication line such as the public optical network shown in the figure, and other base stations, server devices on the core network 140, etc. Communication with various nodes is possible via a predetermined communication interface.

  The aforementioned macrocell base station has a transmission power of about 10 W, for example, and is a wide-area base that covers a macrocell that is a wide-area area with a radius of about several hundred to several kilometers that is installed outdoors in a mobile communication network. It is a station and may be called “Macro e-Node B”, “MeNB”, or the like. The macro cell base station is connected to another base station via a wired communication line, for example, and can communicate with a predetermined communication interface. Further, the macro cell base station is connected to the core network 140 of the mobile communication network via a line termination device and a communication line such as the public optical network shown in the figure, and is connected to various nodes such as a server device on the core network 140. Thus, communication is possible through a predetermined communication interface.

  The base station devices 121 (1) to 121 (N) of the base stations 120 (1) to 120 (N) are, for example, computer devices having a CPU, a memory, etc., an external communication interface unit for the core network 140, a wireless communication unit, etc. By using a predetermined hardware and executing a predetermined program, a handover control described later is executed, or wireless communication with a mobile station that is a user terminal is performed using a predetermined communication method and wireless communication resources. You can communicate.

  In the present embodiment, data (for example, an automobile) transmitted and received by data communication by the mobile station 10 located in the cells 120A (1) to 120A (N) in the vicinity of each of the base stations 120 (1) to 120 (N). MEC (Mobile Edge Computing) servers 151 (1) to 151 (N) are provided as data processing devices for processing related communication application data).

  Each of the MEC servers 151 (1) to 151 (N) is a public optical line via a backhaul line including a predetermined interface (for example, an S1 interface that is a control plane interface between the base station and the core network device). It is connected to a switch (switch) 160B provided on the network 160, and further connected to an EPC (Evolved Packet Core) device 141 as a core network device of the core network 140 via a switch 160C of a gateway.

  The EPC device 141 has an MME (Mobility Management Entity) function and an S-GW (Serving Gateway) function. As an MME function, a sequence control function, a handover control function, a mobility management control function of a mobile station (terminal), a location management function during standby of the mobile station (terminal), and a call (paging) function when receiving an incoming call to the base station apparatus Mobile station (terminal) authentication management function. Examples of the S-GW function include a gateway function, a node function for connecting LTE user data to a 2G or 3G system, and a legal intercept function.

  Note that the MEC servers 151 (1) to 151 (N) may be provided inside the base stations 120 (1) to 120 (N), respectively, or the base stations 120 (1) to 120 (N) and the core network. 140 core network devices 141 may be provided.

  Further, as a communication application related to automobiles, there is a V2X (Vehicle-to-everything) communication application which is communication between an automobile and various things. The V2X communication application includes communication between a vehicle and a mobile communication network (V2N: Vehicle-to-cellular-Network) application, vehicle-to-vehicle communication (V2V: Vehicle-to-Vehicle) application, road-vehicle communication (V2I: Vehicle). -to-roadside-Infrastructure) application, vehicle-to-pedestrian (V2P) application, etc.

  The MEC servers 151 (1) to 151 (N) are arranged closer to the mobile station 10 (mobile edge) that is a user terminal, and compute data that is transmitted and received by an application that is executed by the mobile station 10. Act as a resource. Data processing requested from the mobile station 10 is executed by the MEC servers 151 (1) to 151 (N), and data communication from the mobile station 10 is looped back by the MEC server. Since the communication distance of data communication becomes shorter than when processing is performed (the number of hops of the routed router is reduced), end-to-end transmission delay can be suppressed and low-delay data communication can be realized.

  As described above, since the MEC servers 151 (1) to 151 (N) are provided in the vicinity of the base stations 120 (1) to 120 (N), handover processing between the MEC servers is also necessary at the time of handover between cells. become. Therefore, the delay of the handover process increases, and the communication interruption time associated with the handover process increases.

  Therefore, in the mobile communication system according to the present embodiment, the MEC servers 151 (1) to 151 (N), which are a plurality of distributed hardware resources, are connected to each other via the S1 interface, which is an ultrahigh-speed interface, and the switch 160B. (Mesh ultra-high speed link), the MEC servers 151 (1) to 151 (N) are synchronized with each other in the data processing state and the data storage state to construct one virtualized MEC server (MEC Server virtualization).

  According to the embodiment of FIG. 1, a plurality of cells 120 </ b> A (1) to 120 </ b> A (N) to which the mobile station 10 is handed over due to MEC server virtualization using an ultra-high speed link between MEC servers 151 (1) to 151 (N) Increase in handover processing time during data communication involving data processing in the MEC servers 151 (1) to 151 (N) can be suppressed.

  In the embodiment of FIG. 1, the synchronization of the data processing state and the data storage state among the plurality of MEC servers 151 (1) to 151 (N) reduces the operation cost of MEC server virtualization as follows. You may go to For example, when a difference in state is generated by data processing in any one of the plurality of MEC servers 151 (1) to 151 (N), only the difference information is transmitted to the other MEC server, so that the synchronization is performed. May be performed.

  In the embodiment of FIG. 1, the base stations 120 (1) to 120 (N) and the EPC device 141 as a core network device so as to perform synchronization processing between the plurality of MEC servers 151 (1) to 151 (N). You may provide a synchronous server between. In this case, when a difference between the data processing state and the data storage state of any MEC server occurs, each of the plurality of MEC servers 151 (1) to 151 (N) transmits information on the difference to the synchronization server. The synchronization server transmits the difference information received from the MEC server to another MEC server.

FIG. 2 is an explanatory diagram showing a schematic configuration of a mobile communication system according to another embodiment. In the example of FIG. 2, movements where a plurality of cells 120A (1) to 120A (N) are located in a base that aggregates the traffic of the base stations 120 (1) to 120 (N) (referred to as “traffic aggregation base”). This is an example in which a common MEC server 152 as a centralized data processing device that processes data transmitted and received by data communication by the station 10 is arranged.
In FIG. 2, the same reference numerals are given to portions common to those in FIG. 1 described above, and description thereof is omitted.

  In FIG. 2, the intra-area optical network 161 that aggregates the traffic of the base stations 120 (1) to 120 (N) is more suitable than the core network 140 and the inter-area wide-area optical network 162. N) at a site physically close to N). The distance between the intra-region optical network 161 and each base station 120 (1) to 120 (N) is the same MEC server provided in each base station 120 (1) to 120 (N) and the intra-region optical network 161. The transmission delay is set so as not to cause a problem. The intra-area optical network 161 and the inter-area wide-area optical network 162 may be public optical networks, private optical networks, or high-speed transmission other than optical fibers. It may be a high-speed line network using a medium.

  Each base station apparatus (BSE) 121 (1) to 121 (N) of each base station 120 (1) to 120 (N) is connected to a local area via a backhaul line composed of a predetermined interface (for example, X2 interface). It is connected to a switch (switch) 161A provided in the internal optical network 161.

  Each of the base station apparatuses (BSE) 121 (1) to 121 (N) is connected via an S1 interface that is an ultra-high-speed interface and a switch 161B provided at a traffic aggregation base of the intra-region optical network 161. Are connected to a common MEC server 152. The common MEC server 152 is connected to the EPC device 141 of the core network 140 via the switch 161B of the intra-area optical network 161 and the switches 162A and 162B of the higher inter-area wide-area optical network 162. Yes.

  According to the embodiment of FIG. 2, the handover between the MEC servers is not required between the plurality of base stations 120 (1) to 120 (N) having the same traffic aggregation base in the intra-area optical network 161. An increase in handover processing time when the station 10 performs data communication involving data processing in the MEC server 152 can be suppressed.

  In the embodiment of FIG. 2, the common MEC server 152 includes at least part of functions related to handover control of the EPC device 141 in the core network 140 (for example, at least a gateway function related to handover control and a mobility management control function of the mobile station 10). One function). In this case, transmission / reception of signals or data related to handover control in the base stations 120 (1) to 120 (N) and the mobile station 10 covered by the intra-area optical network 161 is an MEC located at a shorter distance than the EPC device 141. Since it can be performed with the server 152, it is difficult to be affected by the transmission delay of signals and data related to handover control, and the handover control delay can be reliably reduced even when the mobile station 10 is moving at high speed.

  FIG. 3 is an explanatory diagram showing a schematic configuration of a mobile communication system according to still another embodiment. The example of FIG. 3 is an example in which a centrally arranged BBU 123 that aggregates baseband units (BBUs) of a plurality of base stations 120 (1) to 120 (N) is arranged. In FIG. 3, the same reference numerals are given to portions common to those in FIGS. 1 and 2 described above, and description thereof is omitted.

  In FIG. 3, base station apparatuses (BSE) of a plurality of base stations 120 (1) to 120 (N) are respectively connected to overhang radio apparatuses (RRUs) 122 (1) to 122 (N) and baseband processing. A device (BBU: Base Band Unit) 124 (1) to 124 (N) is separated. The baseband processing unit (BBU) 124 (1) -124 (N) of each base station 120 (1) -120 (N) is a regional light that aggregates the traffic of the base stations 120 (1) -120 (N). The centralized BBU 123 is integrated into the line network 161. Baseband processing units (BBUs) 124 (1) to 124 (N) in the centralized BBU 123 correspond to overhang radio units via CPRI (Common Public Radio Interface) which is a base station standard optical interface, respectively. (RRU) 122 (1) to 122 (N). In addition, the baseband processing units (BBU) 124 (1) to 124 (N) in the centralized BBU 123 are provided at the S1 interface, which is an ultra-high-speed interface, and the traffic aggregation base of the regional optical network 161, respectively. It is connected to the common MEC server 152 via the switch 161B. The intra-area optical network 161 and the inter-area wide-area optical network 162 may be public optical networks, private optical networks, or high-speed transmission other than optical fibers. It may be a high-speed line network using a medium.

  According to the embodiment of FIG. 3, handover between MEC servers is not required between a plurality of base stations 120 (1) to 120 (N) having the same traffic aggregation base in the regional optical network 161. An increase in handover processing time when the station 10 performs data communication involving data processing in the MEC server 152 can be suppressed.

  In particular, according to the embodiment of FIG. 3, it is possible to reduce physical optical links compared to the configuration of FIG.

  In the embodiment of FIG. 3 as well, the common MEC server 152 is a part of the functions related to handover control of the EPC device 141 in the core network 140 (for example, the gateway function related to handover control and the mobility management control function of the mobile station 10). At least one of the functions). In this case, transmission and reception of signals and data related to handover control at the base stations 120 (1) to 120 (N) and the mobile station 10 covered by the regional optical network 161 are located at a distance closer to the EPC device 141. Since it can be performed with the server 152, it is difficult to be affected by the transmission delay of signals and data related to handover control, and the handover control delay can be reliably reduced even when the mobile station 10 is moving at high speed.

  Note that the processing steps described in this specification and the components of the mobile communication system, the base station, the mobile station, and the MEC server can be implemented by various means. For example, these steps and components may be implemented in hardware, firmware, software, or a combination thereof.

  Regarding hardware implementation, means such as a processing unit used to realize the above steps and components in an entity (for example, various wireless communication devices, Node B, computer device, hard disk drive device, or optical disk drive device) One or more application specific ICs (ASICs), digital signal processors (DSPs), digital signal processors (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), It may be implemented in a processor, controller, microcontroller, microprocessor, electronic device, other electronic unit designed to perform the functions described herein, a computer, or a combination thereof.

  Also, for firmware and / or software implementation, means such as processing units used to implement the above components may be programs (eg, procedures, functions, modules, instructions) that perform the functions described herein. , Etc.). In general, any computer / processor readable medium that specifically embodies firmware and / or software code is means such as a processing unit used to implement the steps and components described herein. May be used to implement For example, the firmware and / or software code may be stored in a memory, for example, in a control device, and executed by a computer or processor. The memory may be implemented inside the computer or processor, or may be implemented outside the processor. The firmware and / or software code may be, for example, random access memory (RAM), read only memory (ROM), nonvolatile random access memory (NVRAM), programmable read only memory (PROM), electrically erasable PROM (EEPROM) ), FLASH memory, floppy disk, compact disk (CD), digital versatile disk (DVD), magnetic or optical data storage, etc. Good. The code may be executed by one or more computers or processors, and may cause the computers or processors to perform the functional aspects described herein.

  Also, descriptions of embodiments disclosed herein are provided to enable any person skilled in the art to make or use the present disclosure. Various modifications to the present disclosure will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other variations without departing from the spirit or scope of the disclosure. The present disclosure is therefore not limited to the examples and designs described herein, but should be accorded the widest scope consistent with the principles and novel features disclosed herein.

10 Mobile station (terminal, user equipment, communication terminal equipment)
120 (1) to 120 (N) Base station 120A (1) to 120A (N) Cell 121 (1) to 121 (N) Base station apparatus 122 (1) to 122 (N) Overhang radio apparatus (RRU)
123 Centralized BBU
124 (1) to 124 (N) Baseband processing unit (BBU)
140 Core Network 141 Core Network Device 151 (1) to 151 (N) MEC Server 152 MEC Server 200 Road 210 Automobile

Claims (25)

A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
Each of the plurality of cells is a core network formed by the wireless communication device located in the cell, inside the base station of the cell, in the vicinity of the base station of the cell, or between the base station of the cell and the core network device. A cell in which a data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted / received through data communication not via a cell is disposed,
The plurality of data processing devices are connected to each other via a predetermined interface, and when a difference occurs due to a change in a data processing state and a data storage state of the data processing device, information on the difference is transferred to another data processing device. mobile communication system by transmitting, wherein the data processing state and data storage state of the application data of the data processing device are synchronized with each other to.   A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
  Each of the plurality of cells is a core network formed by the wireless communication device located in the cell, inside the base station of the cell, in the vicinity of the base station of the cell, or between the base station of the cell and the core network device. A cell in which a data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted / received through data communication not via a cell is disposed,
  The plurality of data processing devices are one wide area data processing virtualized by being connected to each other via an interface and a switch of an optical network provided between the core network and the plurality of base stations. A mobile communication system, characterized in that a device is constructed and a data processing state and a data storage state of the application data of the data processing device are synchronized with each other.   A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
  Each of the plurality of cells is a core network formed by the wireless communication device located in the cell, inside the base station of the cell, in the vicinity of the base station of the cell, or between the base station of the cell and the core network device. A cell in which a data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted / received through data communication not via a cell is disposed,
  The plurality of data processing devices are one wide area data processing virtualized by being connected to each other via an interface and a switch of an optical network provided between the core network and the plurality of base stations. When a difference is generated due to a change in the data processing state and data storage state of the data processing device, information on the difference is transferred to another data processing device via the interface and switch of the optical network. A mobile communication system, wherein the data processing state and the data storage state of the application data of the data processing device are synchronized with each other by transmitting. The mobile communication system according to any one of claims 1 to 3,
A synchronization server provided between the base station of the cell and the core network device so as to perform synchronization processing between the plurality of data processing devices;
When the difference between the data processing state and the data storage state of the data processing device occurs, each of the plurality of data processing devices transmits information on the difference to the synchronization server,
The mobile communication system, wherein the synchronization server transmits information on the difference received from the data processing device to another data processing device. A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
Application data transmitted and received by the wireless communication device located in each of the plurality of cells between the base station and the core network device of each of the plurality of cells by data communication not via the core network from the wireless communication device have a function to perform the requested data processing, is connected to the plurality of base stations via the interface and the switch of the light line network provided between said core network of the plurality of base stations, said plurality A mobile communication system, characterized in that a centralized data processing device used in common for the base stations is arranged. A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
Gateway function for performing handover control without passing through the core network in data communication by the wireless communication device located in each of the plurality of cells between the base station and the core network device of each of the plurality of cells, and the wireless have at least one of the mobility management control functions of a communication device, coupled to said plurality of base stations via the interface and the switch of the light line network provided between said core network of the plurality of base stations, wherein A mobile communication system comprising a centralized data processing device commonly used for a plurality of base stations . The mobile communication system according to claim 6 , wherein
The centralized data processing device includes at least one of the gateway function and the mobility management control function, and application data transmitted and received by data communication not via a core network by the wireless communication device located in each of the plurality of cells. A mobile communication system having a function of executing data processing requested from a wireless communication device. A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
The base station of each of the plurality of cells includes an antenna and an overhanging radio device arranged in the cell, and a baseband device connected to the overhanging radio device via an optical interface,
The baseband devices of the plurality of cells are centrally arranged in an optical network between the overhanging radio device and the core network device,
Wherein the centralized arranged the plurality of base band, through the interface and the switch of the light line network, transmitted and received data communication not through the core network by the wireless communication apparatus existing in each of the plurality of cells A mobile communication system, wherein a centralized data processing device having a function of executing data processing requested from the wireless communication device for application data is connected. A mobile communication system capable of controlling handover between a plurality of cells based on reception quality information of a mobile radio communication device,
The base station of each of the plurality of cells includes an antenna and an overhanging radio device arranged in the cell, and a baseband device connected to the overhanging radio device via an optical interface,
The baseband devices of the plurality of cells are centrally arranged in an optical network between the overhanging radio device and the core network device,
Handover control not via a core network in data communication by the wireless communication device located in each of the plurality of cells is performed on the plurality of baseband devices arranged centrally via the interface and switch of the optical network. A centralized data processing apparatus having at least one of a gateway function and a mobility management control function of the wireless communication apparatus is connected. The mobile communication system according to claim 9 , wherein
The centralized data processing device includes at least one of the gateway function and the mobility management control function, and application data transmitted and received by data communication not via a core network by the wireless communication device located in each of the plurality of cells. A mobile communication system having a function of executing data processing requested from a wireless communication device. The mobile communication system according to any one of claims 5 to 10 ,
The mobile communication system, wherein the centralized data processing device is arranged at a base that aggregates traffic of base stations of the plurality of cells. The mobile communication system according to any one of claims 5 to 11 ,
The centralized data processing device or the centralized baseband devices are provided in an intra-region optical network and connected to a core network via an inter-region optical network. . The mobile communication system according to any one of claims 1 to 12 ,
The mobile communication system, wherein the mobile radio communication device is a mobile base station. Provided inside the cell base station of the mobile communication system, in the vicinity of the cell base station or between the cell base station and the core network device, and not via the core network by the radio communication device located in the cell A data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted and received by data communication,
With the data processing device of another cell adjacent to the cell, they are connected to each other via a predetermined interface, when the difference occurs the data processing state and data storage state of the data processing apparatus of the cell is changed The data processing device is characterized in that the data processing state and the data storage state of the application data of the data processing device are synchronized with each other by transmitting the difference information to another data processing device.   Provided inside the cell base station of the mobile communication system, in the vicinity of the cell base station or between the cell base station and the core network device, and not via the core network by the radio communication device located in the cell A data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted and received by data communication,
  The data processing device of another cell adjacent to the cell is connected to each other via an interface and a switch of an optical network provided between the core network and the base station. A data processing apparatus, wherein a data processing state and a data storage state of the application data are synchronized with each other.   Provided inside the cell base station of the mobile communication system, in the vicinity of the cell base station or between the cell base station and the core network device, and not via the core network by the radio communication device located in the cell A data processing device having a function of executing data processing requested from the wireless communication device for application data transmitted and received by data communication,
  Data processing of the cell connected to the data processing device of another cell adjacent to the cell via an interface and switch of an optical network provided between the core network and the base station When a difference occurs due to a change in the data processing state and data storage state of the device, the data processing is performed by transmitting information on the difference to another data processing device via the interface and switch of the optical network. A data processing apparatus, wherein a data processing state and a data storage state of the application data of the apparatus are synchronized with each other. The data processing device according to any one of claims 14 to 16 ,
When a difference between the data processing state and the data storage state of the data processing device occurs, information on the difference between the base station of the cell and the core network device so as to perform synchronization processing with the other data processing device A data processing apparatus which transmits to a synchronization server provided therebetween. A data processing device for processing data transmitted and received by data communication by a mobile wireless communication device located in a cell of a mobile communication system,
Request from the wireless communication device for application data transmitted / received by the wireless communication device located in each of the plurality of cells via the core network between the base station of each of the plurality of cells and the core network device. are to have the ability to centralized data processing, is connected to the plurality of base stations via the interface and the switch of the light line network provided between said core network of the plurality of base stations, said plurality A data processing apparatus that is commonly used for base stations . A data processing device for processing data transmitted and received by data communication by a mobile wireless communication device located in a cell of a mobile communication system,
A gateway function provided between a base station of each of a plurality of cells and a core network device, for performing handover control without passing through a core network in data communication by the wireless communication device located in each of the plurality of cells; and have at least one of the mobility management control functions of the wireless communication device, coupled to said plurality of base stations via the interface and the switch of the light line network provided between said core network of the plurality of base stations, A data processing apparatus used in common for the plurality of base stations . The data processing apparatus of claim 19 ,
Requested from the wireless communication device for application data to be transmitted / received by at least one of the gateway function and the mobility management control function and data communication not via a core network by the wireless communication device located in each of the plurality of cells. A data processing apparatus having a function of centrally executing data processing. A data processing device for processing data transmitted and received by data communication by a mobile wireless communication device located in a cell of a mobile communication system,
The base band centralized arranged the plurality of cells between the plurality of cells each overhang wireless device and a core network device, an optical network which is provided between the core network and the plurality of protruding wireless device Concentrated execution of data processing requested from the wireless communication device for application data transmitted and received by data communication not via a core network by the wireless communication device that is connected via an interface and a switch and is located in each of the plurality of cells A data processing apparatus having a function of A data processing device for processing data transmitted and received by data communication by a mobile wireless communication device located in a cell of a mobile communication system,
The base band centralized arranged the plurality of cells between the plurality of cells each overhang wireless device and a core network device, an optical network which is provided between the core network and the plurality of protruding wireless device is connected through the interface and the switch, the mobile management control functionality of a gateway function for performing a handover control without going through the core network in the data communication by the wireless communication apparatus existing in each of the plurality of cells and the wireless communication device A data processing apparatus comprising at least one of the following. The data processing apparatus of claim 22 ,
Requested from the wireless communication device for application data to be transmitted / received by at least one of the gateway function and the mobility management control function and data communication not via a core network by the wireless communication device located in each of the plurality of cells. A data processing apparatus having a function of executing data processing. In any of the data processing apparatus of claims 21 to 23,
A data processing apparatus, wherein the data processing apparatus is arranged at a base that aggregates traffic of base stations of the plurality of cells. 25. A data processing device according to any one of claims 21 to 24 .
A data processing apparatus provided in an intra-region optical network and connected to a core network via an inter-region optical network.