JP6785525B2 - Cellular communication system connection device, communication system, cellular communication system connection method, and program - Google Patents

Description

The present disclosure relates to a cellular communication system connection device, a communication system, a cellular communication system connection method, and a program having an IoT-PF connection function for connecting to the IoT-PF of the cellular communication system in a non-cellular communication system. Is.

In recent years, not only IP data communication but also a wide variety of applications and services such as IoT (Internet of Things) / M2M (Machine to Machine), 4K / 8K high-definition video distribution service, and online games have rapidly become widespread. In particular, the spread of IoT that performs automatic recognition, automatic control, remote measurement, etc. by giving communication functions not only to information / communication devices such as computers but also to various "things" existing in the world and communicating with each other. Is progressing rapidly.

In IoT, it is necessary to deploy many IoT devices in a wide area, so it is important to establish a management method of how to manage IoT devices. As one of the methods for solving this problem, there is IoT-PF (PlatForm) provided in a cellular communication system such as LTE or 3G. The IoT-PF utilizes information in the subscriber DB (DataBase) that manages the communication status, location information, and contract status of terminals possessed by cellular communication systems such as HLR (Home Location Register) and HSS (Home Subscriber Service). , Communication status monitoring of IoT devices (hereinafter collectively referred to as cellular devices) that use a cellular communication system, opening / stopping of communication lines, and location information management are realized.

On the other hand, since there are various use cases of IoT, IoT devices (hereinafter collectively referred to as non-cellular communication systems) that use communication systems other than cellular communication systems (hereinafter collectively referred to as non-cellular communication systems) are used. Also called a non-cellular device). For example, in the case of small and large-scale IoT devices such as sensors, a wireless communication system other than cellular that realizes reduction in power consumption and price of communication devices is used. In addition, when acquiring multiple pieces of information with one IoT device or transmitting a large amount of data such as video, an optical fiber communication system that realizes high throughput at a low price per amount of transmitted data. I will provide a.

However, as of 2017, IoT-PF is not provided in non-cellular communication systems. One of the reasons is that in non-cellular communication systems, there is no C-Plane (Control-Plane) protocol that is exchanged between terminals and communication systems, and there is no subscriber DB such as HLR and HSS. .. Therefore, in order to provide IoT-PF in a non-cellular communication system, it is necessary to realize the C-Plane protocol exchanged between the terminal and the communication system and to construct a subscriber DB.

In addition, some users who carry out IoT use both non-cellular devices and cellular devices. In that case, even if the IoT-PF is realized by the cellular communication system or the non-cellular communication system alone, the cellular device and the non-cellular device cannot be integrated and managed.

Further, in the case of an IoT device that uses a non-cellular communication system, one device may acquire a plurality of pieces of information, or a large number of small identical devices may be arranged. In that case, the current terminal-based IoT-PF is not suitable for operation. Specifically, it is required to manage one IoT device as if it were a plurality of devices, or to manage a plurality of IoT devices collectively, but this cannot be realized by terminal-based management.

Therefore, there is a demand for the realization of IoT-PF that enables flexible and integrated management of IoT devices regardless of the line type without adding major functions to the existing communication system.

For example, as a method of managing terminals in an integrated manner regardless of the line type used, there is a method of exchanging terminal information between a plurality of communication systems as shown in Patent Document 1. In Patent Document 1, it is possible to provide an integrated IoT-PF by enabling the subscriber DB of the communication system to be exchanged between a plurality of communication systems.

Further, as a method of using a non-cellular communication system such as WiFi like a cellular communication system, there is a method of capsulating a cellular protocol as shown in Non-Patent Document 1 with a non-cellular protocol. By accommodating the non-cellular device in the cellular communication system by the method shown in Non-Patent Document 1, it becomes possible to manage the non-cellular device by the IoT-PF provided by the cellular communication system.

Japanese Unexamined Patent Publication No. 2001-285372

WirelessGate, "LTE over Wi-Fi" communication service for IoT ("http://k-tai.watch.impress.co.jp/docs/news/1023020.html", searched on June 5, 2017)

However, the method of Patent Document 1 only describes the method of synchronizing the database, and it is necessary to be able to add new information when the information of the database of each communication system is insufficient. There is a problem that a large function needs to be added to the existing communication system. In addition, since the management is terminal-based, there is also a problem that flexible management cannot be realized.

Further, although the method of Non-Patent Document 1 realizes integrated management of non-cellular devices and cellular devices, there is a problem that it is difficult to realize flexible device management because of terminal-based management. In addition, implementing the capsulating function of the cellular protocol on many non-cellular devices has a problem that a very large addition of functions is required.

Therefore, in order to solve the above problems, the present invention provides a cellular communication system connection device, a communication system, which enables integrated management of non-cellular devices and cellular devices without adding major functions to existing communication systems. It is an object of the present invention to provide a cellular communication system connection method and a program.

In order to achieve the above object, the cellular communication system connection device according to the present invention uses a virtualized cellular base station as a transmission / reception packet of an IoT device connected to a non-cellular network as a transmission / reception packet of a virtualized cellular terminal. It is possible to handle it as a transmission / reception packet of a cellular network via.

Specifically, the cellular communication system connecting device according to the present invention is
One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network.
One or more virtual cellular base stations that connect the virtual cellular terminal and the core device in the cellular network, and
A packet distribution unit that distributes transmission / reception packets of a communication device connected to the non-cellular network to the virtual cellular terminal,
A virtual device that controls the connection relationship between the virtual cellular terminal and the virtual cellular base station and transfers transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the cellular network with the cellular network. Terminal accommodation control unit and
To be equipped.

Further, the communication system according to the present invention is
Located between cellular and non-cellular networks,
One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the cellular network, and connecting the virtual cellular terminal to a core device in the cellular network 1 Forming the above virtual cellular base station,
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. The present invention includes a cellular communication system connection device that transfers the transmission / reception packet of the above as a transmission / reception packet of the cellular network with the cellular network.

Further, the cellular communication system connection method according to the present invention is
One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network, and one or more virtual cellular terminals connecting the virtual cellular terminal and a core device in the cellular network. Form a virtual cellular base station,
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. The transmission / reception packet is transferred to / from the cellular network as a transmission / reception packet of the cellular network.

The present invention arranges a cellular communication system connection device between a cellular network and a non-cellular network, and converts the packet format between them. Therefore, it is not necessary to add a large function to the existing communication system, and the communication device can be integratedly managed in the cellular network regardless of the line type.

Therefore, the present invention provides a cellular communication system connection device, a communication system, a cellular communication system connection method, and a cellular communication system connection method that enable integrated management of non-cellular devices and cellular devices without adding major functions to existing communication systems. A program can be provided.

The cellular communication system connecting device according to the present invention detects the connection state between the communication device connected to the non-cellular network and the non-cellular network, and changes the activation state of the virtual cellular terminal and the connection relationship. It is characterized by further including a device management unit that controls the virtual terminal accommodation control unit. By providing the device management unit, this cellular communication system connection device can manage the state of non-cellular devices in a cellular network.

The virtual cellular terminal of the cellular communication system connection device according to the present invention further has a function of transferring transmission / reception packets of a communication device connected to the non-cellular network to the non-cellular network as transmission / reception packets of the non-cellular network. It is characterized by. This cellular communication system connection device makes it possible to collect information in a data server by properly using a cellular communication system and a non-cellular communication system according to the content of communication.

The program according to the present invention is a program for making a computer function as the cellular communication system connecting device. The cellular communication system connection device according to the present invention can also be realized by a computer and a program, and the program can be recorded on a recording medium or provided through a network.

The present invention provides a cellular communication system connection device, a communication system, a cellular communication system connection method, and a program that enable integrated management of non-cellular devices and cellular devices without adding major functions to existing communication systems. Can be provided.

It is a figure explaining the communication system which concerns on this invention. It is a figure explaining the packet distribution table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the terminal setting table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the virtual terminal accommodation table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the base station setting table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the device management table of IoT-PF. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the base station DB of a cellular network. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the subscriber DB of a cellular network. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the IoT device management DB of IoT-PF. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the IoT device management DB of IoT-PF. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the transmission / reception packet in the communication system which concerns on this invention. It is a figure explaining the transmission / reception packet in the communication system which concerns on this invention. It is a figure explaining the transmission / reception packet in the communication system which concerns on this invention. It is a figure explaining the communication system which concerns on this invention. It is a figure explaining the communication state relevance table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the virtual terminal accommodation table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the IoT device management DB of IoT-PF. It is a figure explaining the virtual terminal accommodation table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the IoT device management DB of IoT-PF. It is a figure explaining the terminal setting table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the IoT device management DB of IoT-PF. It is a figure explaining the communication system which concerns on this invention. It is a figure explaining the packet distribution table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the terminal setting table provided in the cellular communication system connection apparatus which concerns on this invention. It is a figure explaining the cellular communication system connection method which concerns on this invention. It is a figure explaining the transmission / reception packet in the communication system which concerns on this invention.

Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments described below are examples of the present invention, and the present invention is not limited to the following embodiments. In this specification and drawings, the components having the same reference numerals shall indicate the same components.

(Embodiment 1)
FIG. 1 is a configuration diagram showing the IoT data collection system 601 of the present embodiment. The IoT data collection system 601
With the IoT platform 23 in the cellular network 20
One or more virtual cellular terminals 303 having a function of treating transmission / reception packets of IoT (Internet of Things) devices (42, 43) connected to the non-cellular network 10 as transmission / reception packets of the cellular network 20, and virtual cellular terminals 303 and cellular. One or more virtual cellular base stations 309 connecting to the core device 203 in the network 20 are formed.
The transmission / reception packets of the IoT devices (42, 43) connected to the non-cellular network 10 are distributed to the virtual cellular terminal 303, and the connection relationship between the virtual cellular terminal 303 and the virtual cellular base station 309 is controlled to the non-cellular network 10. Connect the connected IoT devices (42, 43) to the IoT platform 23 and
A cellular communication system connection device 3 that transfers transmission / reception packets of IoT devices (42, 43) connected to the non-cellular network 10 to and from the cellular network 20 as transmission / reception packets of the cellular network 20.
To be equipped.

Specifically, the IoT data acquisition system 601 includes a non-cellular communication system 1, a cellular communication system 2, a cellular communication system connection device 3 provided as an extension to the non-cellular communication system 1, an IoT device 4, and the Internet. It is composed of a part 5. In the IoT data acquisition system 601, only the cellular communication system connection device 3 is provided between the non-cellular communication system 1 and the cellular communication system 2, and the IoT-PF23 on the cellular communication system 2 is the IoT device 4 regardless of the line type. Can be flexibly and integratedly managed.

The solid line in FIG. 1 means the connection between the functional units, and the broken line arrow indicates the exchange of control information.

The non-cellular communication system 1 includes a non-cellular network 10 composed of routers and switches to provide communication between connection portions, and a transfer device 11 existing in the non-cellular network 10 and connecting to the cellular communication system connection device 3. , Non-cellular by transmitting and receiving via the OLT (Optical Line Thermal) 12 which is an optical line terminal inside the station, the ONU (Optical Network Unit) 13 which is an optical network unit inside the house, and the wireless device 42 and the wireless radio wave 15. It is composed of a wireless GW (GateWay) 14 that mediates the connection to the network 10 and a wired GW 16 that mediates the connection to the non-cellular network 10 by transmitting and receiving via the wired device 43 and the wired 17. The wireless radio wave 15 is a communication medium between the wireless GW 14 and the wireless device 42, and has a wireless system different from the radio wave used in the cellular system.

The cellular communication system 2 is a cellular base composed of a router or a switch and providing communication between connection portions, and a cellular base that transmits and receives via a cellular device 41 and a cellular radio wave 22 to mediate a connection to the cellular network 20. It is composed of a station 21 and an IoT-PF23.

The cellular network 20 includes a base station DB 201 that manages the information and status of the base station connected to the cellular communication system 2, a subscriber DB 202 that manages the information and status of the terminal connected to the cellular communication system 2. It is composed of a core device 203 that serves as a GW when the cellular device 41 communicates with the Internet unit 5, and a wireless control device 204 that connects to the cellular base station 21 and controls the connection state of the cellular device 41. Here, the subscriber DB 202 is assumed to be HLR or HSS, and the IMSI (International Mobile Subscriber Identity) is assumed as the identification information of the terminal managed by the subscriber DB 202. The core device 203 assumes P-GW (Packet data network Gateway) and S-GW (Serving Gateway) defined by 3GPP. The wireless control device 204 assumes an MME (Mobile Management Entry) defined by 3GPP.

The IoT-PF23 includes an IoT device management DB 231 that manages the information and status of the IoT device, a VPN router 232 for connecting the VPN router 511 and the VPN 52 in the cloud 51, and a terminal and a management target on the cellular communication system 2. It is composed of a device management table 233 that describes IoT device association information.

The cellular communication system connection device 3 is
One or more virtual cellular terminals 303 having a function of treating the transmission / reception packets of the IoT devices (42, 43) connected to the non-cellular network 10 as the transmission / reception packets of the cellular network 20.
One or more virtual cellular base stations 309 connecting the virtual cellular terminal 303 and the core device 203 in the cellular network 20 and
A packet distribution unit 302 that distributes transmitted / received packets of IoT devices (42, 43) connected to the non-cellular network 10 to a virtual cellular terminal 303, and
By controlling the connection relationship between the virtual cellular terminal 303 and the virtual cellular base station 309, the IoT devices (42, 43) connected to the non-cellular network 10 are connected to the IoT platform 23 in the cellular network 20 to connect the non-cellular network. A virtual terminal accommodation control unit 306 that transfers the transmission / reception packets of the IoT devices (42, 43) connected to the 10 as transmission / reception packets of the cellular network 20 to and from the cellular network 20.
To be equipped.

Specifically, the cellular communication system connection device 3 has a packet distribution unit 301 that distributes packets to the virtual cellular terminal 303 based on the information read from the packet distribution table 302, and a packet distribution table 302 that describes the distribution rules of the packet distribution unit 301. And a function to handle the transmission / reception packets of the wireless device 42 and the wired device 43 as transmission / reception packets of the cellular communication system, and a function to operate a protocol for connecting to the core device 203 and the wireless control device 204 via the virtual cellular base station 308. A virtual cellular terminal 303 composed of a function having terminal identification information on a cellular communication system, a virtual cellular terminal control unit 304 that controls a virtual cellular terminal based on information read from a terminal setting table 305, and a virtual cellular terminal. The terminal setting table 305 in which control information is described, the virtual terminal accommodation control unit 306 that controls the connection relationship between the virtual cellular terminal 303 and the virtual cellular base station 310 based on the information read from the virtual terminal accommodation table 307, and the virtual cellular A virtual base station control unit that controls the settings of a virtual cellular base station based on the information read from the virtual terminal accommodation table 307 that describes the connection relationship information between the terminal 303 and the virtual cellular base station 310 and the base station setting table 309. It is composed of 308, a base station setting table 309 in which control information of a virtual cellular base station is described, and a virtual cellular base station 310 for connecting a virtual cellular terminal 303 and a core device 203 in a cellular network 20. .. Here, the IMSI is assumed as the terminal identification information possessed by the virtual cellular terminal 303, and the text described at the lower part of the virtual cellular terminal 303 indicates the IMSI possessed by each virtual cellular terminal.

The IoT device 4 has a function of transmitting IoT data acquired by a device such as a sensor provided while operating as a communication terminal to the data server 512 of the cloud 51 (hereinafter, collectively referred to as IoT data transmission). In this embodiment, the IoT device 4 is a cellular device 41, a wireless device 42, and a wired device 43.

The cellular device 41 transmits IoT data by connecting to the cellular base station 21 via the cellular radio wave 22 while operating as a terminal of the cellular communication system. While operating as a terminal of a non-cellular communication system, the wireless device 42 transmits IoT data by connecting to the wireless GW 14 via a wireless radio wave 15 which is a radio wave different from the cellular radio wave. The wired device 43 transmits IoT data by connecting to the wired GW 16 via the wired 17 while operating as a terminal of a non-cellular communication system.

The name of the terminal in this embodiment is shown in () of the IoT device 4 in FIG. The IMSI of each cellular device is shown at the bottom of the cellular device 41 in FIG. Further, the IP address of each IoT device is shown at the bottom of the wireless device 42 and the wired device 43 in FIG.

The Internet unit 5 is composed of an Internet 50, a cloud 51, and a VPN 52 indicating a VPN line connecting the IoT-PF23 and the cloud 51.

The cloud 51 is composed of a VPN router 511 that connects a VPN router 232 and a VPN 52 in the IoT-PF, and a data server 512 that receives and stores IoT data transmitted from the IoT device 4. The IP address of each data server is shown at the bottom of the data server 512.

Next, the setting information of FIGS. 2 to 6 preset by the provider of the communication system when the present embodiment is configured will be described.

FIG. 2 shows the specific setting contents of the packet distribution table 302 in the present embodiment. The packet distribution table 302 shows a distribution priority indicating the application order of distribution rules, an identifier used when distributing packets, a transfer destination GW of a downlink packet matching the identifier, and a transfer destination virtual terminal of an uplink packet matching the identifier. And, it is composed of.

FIG. 3 shows the specific setting contents of the terminal setting table 305 in the present embodiment. The terminal setting table 305 has a table for each virtual cellular terminal, and is composed of a start state indicating whether or not the virtual cellular terminal is activated and a connection destination core device indicating the core device 203 to be connected.

FIG. 4 shows the specific setting contents of the virtual terminal accommodating table 307 in the present embodiment. The virtual terminal accommodating table 307 includes a virtual cellular terminal name indicating the target virtual cellular terminal 303, an accommodating destination virtual cellular base station name indicating the virtual cellular base station to which the virtual cellular terminal 303 is connected, and the virtual cellular terminal 303. It is composed of a connection state indicating the connection state of the virtual cellular base station 307 and a connection state indicating the connection state of the virtual cellular base station 307.

FIG. 5 shows the specific setting contents of the base station setting table 309 in the present embodiment. The base station setting table 309 has a table for each virtual cellular base station 307, and has an activation state indicating whether or not the virtual cellular base station 307 is activated, and latitude information and longitude indicating the virtual position of the virtual cellular base station. It consists of information and.

FIG. 6 shows the specific setting contents of the device management table 233 in the present embodiment. The device management table 233 is composed of an IMSI of the terminal to be managed by the IoT-PF and a device name indicating the name of the IoT device having the IMSI.

The operation in this embodiment will be described below. The operations in this embodiment are from the pre-processing S1 which is a process for managing the non-cellular devices 42 to 43 by the IoT-PF23, the management process S2 which is periodically executed after the pre-processing S1 is executed, and the IoT device 4. It is composed of an uplink communication process S3 to the cloud 5 and a downlink communication process S4 from the cloud 5 to the IoT device 4.

FIG. 7 shows the contents of the preprocessing S1. The preprocessing S1 includes a virtual cellular base station connection process S101 in which the virtual cellular base station 310 connects to the wireless control device 204, a virtual cellular terminal connection process S102 in which the virtual cellular terminal 303 connects to the cellular network 20, and IoT-PF. It consists of a device registration process S103 for registering a device to be managed.

FIG. 8 shows the contents of the virtual cellular base station connection process S101. First, the virtual cellular base station 310 is connected to the wireless control device 204 (step S101-1). The connection process in step S101-1 assumes the connection process of the S1-MME interface defined by 3GPP as an example. Next, the wireless control device 204 registers the information of the virtual cellular base station 310 in the base station DB 201 (step S101-2).

FIG. 9 shows the base station DB 201 before and after the implementation of the virtual cellular base station connection process S101 in this embodiment. FIG. 9A shows a state of the base station DB201 before the virtual cellular base station connection process S101 is executed, and FIG. 9B shows a state of the base station DB201 after the virtual cellular base station connection process S101 is executed. The base station DB 201 is composed of a base station name indicating the name of the base station, a connection state of the base station, and latitude information and longitude information indicating the position of the base station. As shown in FIG. 9, by adopting the present embodiment and executing the virtual cellular base station connection process S101, the virtual cellular base station 309 is connected to the cellular communication system 2 in the same manner as the cellular base station 21. Become.

FIG. 10 shows the contents of the virtual cellular terminal connection process S102. First, the virtual cellular terminal 303 is connected to the virtual cellular base station 309 distributed by the virtual terminal accommodating unit 306 (step S102-1). The connection process in step S102-1 assumes the process of RRC Connection Establishment defined by 3GPP as an example. Next, the virtual cellular terminal 303 connects to the wireless control device 204 and the connection destination core device 203 set by the virtual terminal control unit via the virtual cellular base station 309 (step S102-2). The connection process in step S102-2 assumes the LTE attack process defined by 3GPP as an example. Finally, the wireless control device 204 and the core device 203 reflect the information of the virtual cellular terminal 303 in the subscriber DB (step S102-3).

FIG. 11 shows the subscriber DB 202 before and after the implementation of the virtual cellular terminal connection process S102 in this embodiment. FIG. 11A shows the state of the subscriber DB 202 before the virtual cellular terminal connection process S102 is executed, and FIG. 11B shows the state of the subscriber DB 202 after the virtual cellular terminal connection process S102 is executed. The subscriber DB 202 includes an IMSI which is terminal authentication information possessed by the cellular device 41 and the virtual cellular terminal 303, a contract state indicating whether or not there is a communication contract between the cellular device 41 and the virtual cellular terminal 303, and the cellular device 41 and the virtual cellular terminal 303. Area base station information indicating the connected cellular base station, core device information indicating the connected core device 203 of the cellular device 41 and the virtual cellular terminal 303, and the cellular device 41 and the virtual cellular device from the core device 203. It is composed of IP address information indicating the IP address assigned to the terminal 303 and cumulative communication amount information indicating the cumulative communication amount of the cellular device 41 and the virtual cellular terminal 303. As shown in FIG. 11, by adopting this embodiment, it is possible to connect and manage the virtual cellular terminal 303 to the cellular network 20 in the same manner as the cellular device 41.

FIG. 12 shows the contents of the device registration process S103. The IoT-PF23 reads the association information between the IMSI and the IoT device from the device management table 233, and registers the read information in the IoT device management DB.

FIG. 13 shows the IoT device management DB 231 before and after the device registration process S103 is executed. FIG. 13 (A) shows the state of the IoT device management DB 231 before the device registration process S103 is executed, and FIG. 13 (B) shows the state of the IoT device management DB 231 after the device registration process S103 is executed. The IoT device management DB 231 includes the device name of the IoT device to be managed, IMSI which is terminal authentication information possessed by the cellular device 41 and the virtual cellular terminal 303 corresponding to the IoT device, and the cellular device 41 and the virtual cellular terminal corresponding to the IoT device. The contract status indicating the presence or absence of a communication contract of the terminal 303, the communication status indicating the presence or absence of the cellular network 20 connection of the cellular device 41 and the virtual cellular terminal 303 corresponding to the IoT device, and the cellular device 41 and the virtual cellular terminal corresponding to the IoT device. Estimated position information showing the position information of the cellular base station to which 303 is connected as the existence position of a pseudo IoT device, and IP address information assigned to the cellular device 41 corresponding to the IoT device and the virtual cellular terminal 303. , The cumulative communication volume of the cellular device 41 corresponding to the IoT device and the virtual cellular terminal 303. As shown in FIG. 13, by adopting this embodiment, the non-cellular terminal and the cellular terminal can be registered on the same IoT-PF, and a plurality of non-cellular terminals can be registered as one IoT device. , One non-cellular terminal can be registered as a plurality of IoT devices.

FIG. 14 shows the contents of the management process S2. The management process S2 includes a device information update process S201.

FIG. 15 shows the contents of the device information update process S201. First, the IoT-PF23 reads the information about the IMSI described in the device management table 233 from the subscriber DB 201 (step S201-1). Next, the IoT-PF23 reads the information about the base station name read in step S201-1 from the base station DB 202 (step S201-2). Finally, the IoT-PF23 reflects the information read in steps S201-1 and S201-2 in the IoT device management DB 231 (step S201-3).

FIG. 16 shows the contents of the IoT device management DB 231 after the device information update process S201 is executed. By adopting this embodiment, the non-cellular terminal and the cellular terminal are managed on the same IoT-PF, a plurality of non-cellular terminals are managed as one IoT device, and one non-cellular terminal is managed by a plurality of IoT devices. It becomes possible to manage as.

FIG. 17 shows the contents of the uplink communication process S3. First, the wireless device 42 or the wired device 43 transfers the acquired IoT data to the wireless GW 14 or the wired GW 16 as a destination packet by the data server 512 (step S301). The wireless GW 14 or the wired GW 16 transfers the packet to the packet distribution unit 301 via the non-cellular network 10 (step S302). The packet distribution unit 301 transfers the packet to the virtual cellular terminal 303 based on the description in the packet distribution table 302 (step S303). The virtual cellular terminal 303 converts the packet into its own transmission packet (step S304). The process of step S304 assumes NAPT (Network Address Port Translation) as an example. The virtual cellular terminal 303 transfers the packet to the virtual cellular base station 309 to which the packet is connected (step S305). The virtual cellular base station 309 transfers the packet to the core device 203 via the cellular network 20 (step S306). The core device 203 forwards the packet to the data server 512 via the VPN router 232 and the VPN router 511 (step S307). It is assumed that network settings such as routing required for each process are appropriately performed.

FIG. 18 shows the contents of the downlink communication process S4. First, in the data server 512, the virtual cellular terminal 303 transfers the destination packet to the core device 203 via the VPN router 232 and the VPN router 511 (step S401). The core device 203 transfers the packet to the virtual cellular base station 309 via the cellular network 20 (step S402). The virtual cellular base station 309 forwards the packet to the destination virtual cellular terminal 303 (step S403). The virtual cellular terminal 303 converts the packet into a transmission packet to the wireless device 42 or the wired device 43 (step S404). The process of step S404 assumes NAPT as an example. The virtual cellular terminal 303 transfers the packet to the packet distribution unit 301 (step S405). The packet distribution unit 301 forwards the packet to the wireless GW 14 or the wired GW 16 based on the description in the packet distribution table 302 (step S406). The wireless GW 14 or the wired GW 16 forwards the packet to the destination wireless device 42 or the wired device 43 (step S407). It is assumed that network settings such as routing required for each process are appropriately performed.

FIG. 19 shows an example when the uplink communication process S3 is applied to the wireless device 42 (waterway meter) of FIG. As shown in the figure, by adopting this embodiment, the IoT data transmitted by the non-cellular device can be collected in the data server via the cellular network, so that the communication state of the non-cellular device can be measured by the IoT-PF. It will be possible to perform integrated management with. Since the downlink communication process only replaces the transmission / reception destinations in FIG. 19, the description is omitted.

FIG. 20 shows an example when the uplink communication process S3 is applied to the wireless device 42 (thermometer), the wired device 43 (barometer), and the wired device 43 (hygrometer) of FIG. As shown in the figure, by adopting this embodiment, IoT data transmitted by a plurality of non-cellular devices can be collected in a data server as IoT data from a single cellular terminal, and thus a plurality of non-cellular devices can be collected. The communication status of devices can be managed collectively by IoT-PF. Since the downlink communication process only replaces the transmission / reception destinations in FIG. 20, the description is omitted.

FIG. 21 shows an example when the uplink communication process S3 is applied to the wired device 43 (surveillance camera with a motion sensor) of FIG. As shown in the figure, by adopting this embodiment, the IoT data transmitted by a single non-cellular device can be collected in the data server as IoT data from a plurality of cellular terminals. The communication status of non-cellular devices can be divided and managed by IoT-PF. Since the downlink communication process only replaces the transmission / reception destinations in FIG. 21, the description is omitted.

(Embodiment 2)
FIG. 22 is a configuration diagram showing the IoT data collection system 602 of the present embodiment. The IoT data collection system 602 detects the connection state between the IoT devices (42, 43) connected to the non-cellular network 10 and the non-cellular network 10 in the IoT data collection system 601 of FIG. 1, and detects the connection state of the virtual cellular terminal 303. A device management unit that changes the connection relationship between the state and the virtual terminal accommodation control unit 306 is further provided. In the present embodiment, the device management unit is the communication state receiving function 310.

By adopting this configuration, the IoT data collection system 602 reflects the state change of the non-cellular communication system 1 in the operation of the cellular communication system connection device 3 by utilizing the basic state change notification function of the non-cellular communication system. As a result, it becomes possible to manage the communication state of the non-cellular devices 42 to 43 in the IoT-PF23.

Hereinafter, the configuration of the present embodiment will be described focusing on the differences from FIG.

The communication status notification function 18 can be provided for each element in the non-cellular communication system 1, and has a function of notifying the communication status reception function 310 of the status of the non-cellular communication system as non-cellular communication system status information. As an example of the means for notifying, SNMP (Simple Network Management Protocol) is assumed, and it is a function usually possessed by a device in a general network.

The communication status reception function 310 is a functional unit existing in the cellular communication system connection device 3, receives the non-cellular communication system status information notified from the communication status notification function 18, and is described in the communication status relevance table 311. Based on this, it has a function of rewriting the contents of the terminal setting table 305 and the virtual terminal accommodation table 307.

The communication state relevance table 311 is a functional unit existing in the cellular communication system connection device 3, and how to rewrite the terminal setting table 305 and the virtual terminal accommodation table 307 when the non-cellular communication system state information is received. The rule is described.

In addition to the function of the packet distribution unit 301 of FIG. 1, the packet distribution unit 312 has a function of transferring a packet of non-cellular communication system status information notified from the communication status notification function 18 to the communication status reception function 310. Have.

In addition, the contents added for the explanation of this embodiment will be described. The MAC (Media Access Control) address of the wireless device 42 is described at the bottom of the wireless device 42. Further, in the wired 17, the port number of the wired GW 16 used by the wired is described.

FIG. 23 shows the contents of the communication state relevance table 311 in the present embodiment. The communication status relevance table 311 is composed of a notification source and notification content of the non-cellular communication system status information, and rewriting contents of the terminal setting table 305 and the virtual terminal accommodation table 307 for the non-cellular communication system status information. ..

Other setting contents in this embodiment are the same as the contents of FIGS. 2 to 6.

The operation of this embodiment will be described below.

FIG. 24 shows the contents of the non-cellular communication system state reflection process S5 that reflects the state change of the non-cellular communication system in the operation of the cellular communication system connection device 3. First, when the communication status notification function 18 detects a state change of the non-cellular communication system 1, the detected content is transmitted to the communication status reception function 310 as non-cellular communication system status information (step S501). Next, the communication status reception function rewrites the contents of the terminal setting table 305 and the virtual terminal accommodation table 307 based on the received non-cellular communication system status information and the description of the communication status relevance table (step S502). Further, the virtual terminal control unit 304 and the virtual terminal accommodation control unit 306 control the accommodation state of the virtual cellular terminal 303 and the virtual cellular terminal 303 based on the contents of the rewritten terminal setting table 305 and the virtual terminal accommodation table 307. Step S503). Finally, the virtual cellular terminal 303 performs control communication with the cellular communication system based on the control content of step S503 (step S504). In the process of step S504, for example, when the activation state of the virtual cellular terminal 303 is turned off or the connection between the virtual cellular terminal 303 and the virtual cellular base station 309 is disconnected, the LTE datach route defined by 3GPP is used. When only the virtual cellular base station 309 in which the virtual cellular terminal 303 is accommodated is changed, it is assumed that the LTE Handover probe specified in 3GPP is executed as an example.

The operation of reflecting the state change of the non-cellular communication system in the IoT-PF is the same as the management process S2 in the first embodiment.

An actual operation example of the non-cellular communication system state reflection process S3 will be described with some specific examples.

[Case A]
Case A is a case where the connection between the wireless device 42 (waterway meter) and the wireless GW # AA is cut off.
When the connection of the wireless device 42 (water channel meter) is disconnected, the communication status notification function #AA notifies the communication status reception function 310 that the connection disconnection of MAC: CCCC ... has been detected as non-cellular communication system status information. Transmit (step S501). The communication status reception function 310 determines that the received non-cellular communication system information matches the # 1 entry in the communication status-related table 311 and changes the connection status of the virtual cellular terminal # 1 in the virtual terminal accommodation table 307 without connection. (Step S502). As a result of step S502, the contents of the virtual terminal accommodating table 307 are changed as shown in FIGS. 4 to 25. The virtual terminal accommodating control unit 306 disconnects the virtual cellular terminal # 1 and the virtual cellular base station # X based on the contents of FIG. 25 (step S503). The virtual cellular terminal # 1 performs LTE datach process communication with the cellular communication system 2 based on the control content of step S503 (step S504). After that, the IoT-PF23 executes the management process S2.

FIG. 26 shows the contents of the IoT device management DB 231 after performing the non-cellular communication system state reflection process S3 and the management process S2 in case A. As shown in the figure, it can be seen that by adopting this embodiment, it is possible to grasp the situation in which the connection between the wireless device 42 (water channel meter) and the wireless GW # AA is disconnected in the IoT-PF23.

[Case B]
Case B is a case where the wireless device 42 (water channel meter) moves and the connection destination is changed from wireless GW # AA to wireless GW # BB.
When the wireless device 42 (waterway meter) changes the connection destination from wireless GW # AA to wireless GW # BB, the communication status notification function #AA detects a disconnection of MAC: CCCC ... in non-cellular communication. It is transmitted to the communication status receiving function 310 as system status information. At the same time, the communication status notification function #BB transmits to the communication status reception function 310 as non-cellular communication system status information that the connection establishment of MAC: CCCC ... Has been detected (step S501). The communication state reception function 310 determines that the received non-cellular communication system information matches the # 6 entry of the communication state-related table 311 and virtualizes the accommodation virtual cellular base station of the virtual cellular terminal # 1 in the virtual terminal accommodation table 307. Change to cellular base station #Y (step S502). As a result of step S502, the contents of the virtual terminal accommodating table 307 are changed as shown in FIGS. 4 to 27. The virtual terminal accommodation control unit 306 changes the connection destination of the virtual cellular terminal # 1 to the virtual cellular base station # Y based on the contents of FIG. 27 (step S503). The virtual cellular terminal # 1 performs LTE Handover-procedure communication with the cellular communication system 2 based on the control content of step S503 (step S504). After that, the IoT-PF23 executes the management process S2.

FIG. 28 shows the contents of the IoT device management DB 231 after performing the non-cellular communication system state reflection process S3 and the management process S2 in case B. As shown in the figure, by adopting this embodiment, it is possible to grasp the situation in which the wireless device 42 (water channel meter) moves in the IoT-PF23 and the connection destination is changed from the wireless GW # AA to the wireless GW # BB. I know I can do it.

[Case C]
Case C is a case where the link between the OLT 12 and the ONU 13 is broken and all the wired devices 43 cannot be connected to the non-cellular network system.
When the link between the OLT 12 and the ONU 13 is broken, the communication status notification function # DD transmits to the communication status receiving function 310 as non-cellular communication system status information that the link with the ONU is broken (step S501). .. The communication status reception function 310 determines that the received non-cellular communication system information matches the # 8 entry in the communication status-related table 311 and sets the activation status of the virtual cellular terminal # 3 and the virtual cellular terminal # 4 in the terminal setting table 305. Change to off (step S502). As a result of step S502, the contents of the terminal setting table 305 are changed as shown in FIGS. 3 to 29. The virtual terminal control unit 304 turns off the activation states of the virtual cellular terminal # 3 and the virtual cellular terminal # 4 based on the contents of FIG. 29 (step S503). The virtual cellular terminal # 3 and the virtual cellular terminal # 4 perform LTE detach process communication with the cellular communication system 2 based on the control content of step S503 (step S504). After that, the IoT-PF23 executes the management process S2.

FIG. 30 shows the contents of the IoT device management DB 231 after performing the non-cellular communication system state reflection process S3 and the management process S2 in the case C. As shown in the figure, by adopting this embodiment, it is possible to grasp the situation in which the link between the OLT 12 and the ONU 13 is broken in the IoT-PF23 and all the wired devices 43 cannot be connected to the non-cellular network system. Understand.

The reason why the activation state of the virtual cellular terminal # 2 is not turned off in this case is that the communication of the wireless device (thermometer) of the virtual cellular terminal # 2 remains normal. However, in some cases, the activation state of the virtual cellular terminal # 2 may be turned off when communication with one or more IoT devices belonging to the virtual cellular terminal 303 becomes impossible. In this way, the state change of the non-cellular communication system and the contents of table rewriting can be freely set according to the usage situation and requirements.

(Embodiment 3)
FIG. 31 is a configuration diagram showing the IoT data collection system 603 of the present embodiment. In the IoT data collection system 603, at least one of the virtual cellular terminals 303 of the IoT data collection system 601 in FIG. 1 is a virtual dual terminal 313. The virtual dual terminal 313 further has a function of treating the transmission / reception packet of the IoT device connected to the non-cellular network as the transmission / reception packet of the non-cellular network.

By adopting this configuration, the IoT data collection system 603 manages the non-cellular devices 42 to 43 by the IoT-PF23, and the IoT data transmitted by the non-cellular devices 42 to 43 is a data server via the non-cellular communication system 10. It becomes possible to transmit to 512.

Hereinafter, the configuration of the present embodiment will be described focusing on the differences from FIG.

The virtual dual terminal 313 is a functional unit existing in the cellular communication system connection device 3, and connects the cellular communication unit 313-1 having the same communication function as the virtual cellular terminal 303 with the non-cellular communication system to transmit packets. It is composed of a non-cellular communication unit 313-2 for transmission and reception, and a system distribution unit 313-3 having a function of distributing packets received by the virtual dual terminal 313 to the cellular communication unit 133-1 or the non-cellular communication unit 313-2. To.

The virtual terminal control unit 314 has a function of controlling the operation of the virtual dual terminal according to the description in the terminal setting table 315, in addition to the function of the virtual terminal control unit 304 of FIG.

In the terminal setting table 315, in addition to the functions of the terminal setting table of FIG. 1, the operation settings of the virtual dual terminal 313 are described.

The packet distribution unit 316 has a function of distributing packets to the virtual dual terminal 313 in addition to the function of the packet distribution unit 301 of FIG.

FIG. 32 shows the contents of the packet distribution table 302 in this embodiment. Since it is the same as FIG. 3 except for the specific description, the explanation is omitted.

FIG. 33 shows the contents of the terminal setting table 315 in this embodiment. The difference from FIG. 3 is that the settings for the virtual dual terminal 313 are described. Specifically, the information of the packet identifier to be communicated by the non-cellular communication unit 313-1 and the information of the packet identifier to be communicated by the cellular communication unit 313-2 are described.

Other setting contents in this embodiment are the same as the contents of FIGS. 4 to 6.

The actual operation of this embodiment will be described below.

FIG. 34 shows the contents of the uplink communication process S6. The contents of steps S601 to S602 are the same as those of steps S301 to S302. The packet distribution unit 316 transfers the packet to the system distribution unit 313-3 in the virtual cellular terminal 303 or the virtual dual terminal 313 (step S603). The system distribution unit 313-3 distributes the packet to the cellular communication unit 313-1 or the non-cellular communication unit 313-2 based on the description in the terminal setting table 315 (step S604). In the case of a packet distributed to the non-cellular communication unit 313-2, the non-cellular communication unit 313-2 transfers the packet to the data server 512 via the non-cellular network 10 and the Internet 50 (step S605). In the case of a packet distributed to the cellular communication unit, the cellular communication unit 313-1 transfers the packet to the virtual cellular base station to which the packet is connected (step S606). The contents of steps S607 to S608 are the same as the contents of steps S306 to S307.

FIG. 35 shows an example of applying the uplink communication process S6 to the wired device 43 (surveillance camera with a motion sensor) of FIG. 31. By adopting this embodiment, not only the IoT data transmitted by a single non-cellular device is transmitted as IoT data from the cellular terminal, but also the cellular communication system and the non-cellular communication system are used properly according to the content of communication. Since it can be collected in the data server, the communication status of the non-cellular device can be managed by IoT-PF while using the non-cellular communication system.

1: Non-cellular communication system 10: Non-cellular network 11: Transfer device 12: OLT
13: ONU
14: Wireless GW
15: Wireless radio wave 16: Wired GW
17: Wired 2: Cellular communication system 20: Cellular network 21: Cellular base station 22: Cellular radio wave 23: IoT-PF
201: Base station DB
202: Subscriber DB
203: Core device 204: Wireless control device 231: IoT device management DB
232: VPN router 233: Device management table 3: Cellular communication system connection device 301: Packet distribution unit 302: Packet distribution table 303: Virtual cellular terminal 304: Virtual cellular terminal control unit 305: Terminal setting table 306: Virtual terminal accommodation control unit 307: Virtual terminal accommodation table 308: Virtual base station control unit 309: Base station setting table 310: Virtual cellular base station 311: Communication status relevance table 312: Packet distribution unit 313: Virtual dual terminal 314: Virtual terminal control unit 315: Terminal setting table 316: Packet distribution unit 4: IoT device 41: Cellular device 42: Wireless device 43: Wired device 5: Internet unit 51: Cloud 52: VPN
511: VPN router 512: Data server 601-603: IoT data collection system

Claims (7)

One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network.
One or more virtual cellular base stations that connect the virtual cellular terminal and the core device in the cellular network, and
A packet distribution unit that distributes transmission / reception packets of a communication device connected to the non-cellular network to the virtual cellular terminal,
A virtual device that controls the connection relationship between the virtual cellular terminal and the virtual cellular base station and transfers transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the cellular network with the cellular network. Terminal accommodation control unit and
Device management that detects the connection state between the communication device connected to the non-cellular network and the non-cellular network, and controls the virtual terminal accommodation control unit so as to change the activation state of the virtual cellular terminal and the connection relationship. Department and
A cellular communication system connection device comprising. A function that handles transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network, and transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the non-cellular network with the non-cellular network . One or more virtual cellular terminals that have the ability to transfer between
One or more virtual cellular base stations that connect the virtual cellular terminal and the core device in the cellular network, and
A packet distribution unit that distributes transmission / reception packets of a communication device connected to the non-cellular network to the virtual cellular terminal,
A virtual device that controls the connection relationship between the virtual cellular terminal and the virtual cellular base station and transfers transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the cellular network with the cellular network. Terminal accommodation control unit and
A cellular communication system connection device comprising. Located between cellular and non-cellular networks,
One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the cellular network, and connecting the virtual cellular terminal to a core device in the cellular network 1 Forming the above virtual cellular base station,
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. The transmission / reception packet of the above is transferred to and from the cellular network as a transmission / reception packet of the cellular network, and the connection state between the communication device connected to the non-cellular network and the non-cellular network is detected to detect the connection state of the virtual cellular terminal. A communication system including a cellular communication system connection device that changes the activation state and the connection relationship . Located between cellular and non-cellular networks,
The function of treating the transmission / reception packet of the communication device connected to the non-cellular network as the transmission / reception packet of the cellular network, and the transmission / reception packet of the communication device connected to the non-cellular network as the transmission / reception packet of the non-cellular network. One or more virtual cellular terminals having a function of transferring to and from the network, and one or more virtual cellular base stations connecting the virtual cellular terminal and the core device in the cellular network are formed.
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. Cellular communication system connection device that transfers the transmission / reception packet of the above as a transmission / reception packet of the cellular network to the cellular network.
Communication system including. One or more virtual cellular terminals having a function of treating transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network, and one or more virtual cellular terminals connecting the virtual cellular terminal and a core device in the cellular network. Form a virtual cellular base station,
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. The transmission / reception packet of the above is transferred to and from the cellular network as a transmission / reception packet of the cellular network, and the connection state between the communication device connected to the non-cellular network and the non-cellular network is detected to detect the connection state of the virtual cellular terminal. A cellular communication system connection method characterized in that the activation state and the connection relationship are changed . A function that handles transmission / reception packets of a communication device connected to a non-cellular network as transmission / reception packets of a cellular network, and transmission / reception packets of a communication device connected to the non-cellular network as transmission / reception packets of the non-cellular network with the non-cellular network. One or more virtual cellular terminals having a function of transferring between them, and one or more virtual cellular base stations connecting the virtual cellular terminal and a core device in the cellular network are formed.
A communication device connected to the non-cellular network by distributing the transmission / reception packets of the communication device connected to the non-cellular network to the virtual cellular terminal and controlling the connection relationship between the virtual cellular terminal and the virtual cellular base station. A cellular communication system connection method, characterized in that a transmission / reception packet of the above is transferred as a transmission / reception packet of the cellular network to the cellular network. A program for operating a computer as the cellular communication system connecting device according to claim 1 or 2 .

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