JPWO2017169302A1 - Wireless communication system and wireless communication method - Google Patents

Abstract

  In dual mode mobile stations that simultaneously support LTE mobile stations and mobile stations of other private wireless systems, simultaneous communication and group communication that are unlikely to generate echoes are realized. In the wireless communication system of the present invention, the dual mode mobile station writes a mobile station unique number of a private radio in a predetermined area in the USIM, and when transmitting in the LTE mobile station mode, the SIP-URI or SIPS-URI contains the USIM in the USIM. Use the mobile radio unique number of the private radio. When relaying voice data from the LTE network to the private wireless network, the private wireless network acquires the mobile station unique number from the SIP-URI or SIPS-URI that indicates the transmission source of the LTE network, and sends the voice data to the private wireless network. Set as the sender number when relaying.

Description

  The present invention relates to a wireless communication system and a wireless communication method.

  3GPP TS 24.228 “Signalling flows for the IP multimedia call control based on Session Initiation Protocol (SIP) and Session Description Protocol (3GPP) SDP); Stage 3 "and 3GPP TS 24.229" IP Multimedia Call Control Protocol based on Session Initiation Protocol (SIP) and Session Description Protocol (SDP); Stage 3 ", the Internet Protocol (hereinafter referred to as IP) and An IP multimedia subsystem (hereinafter referred to as IMS) based on Session Initiation Protocol (hereinafter referred to as SIP) is used.

On the other hand, for example, in business communication systems such as ARIB STD-T61 and ARIB STD-T79 (private communication system, hereinafter also referred to as business wireless network), a unique protocol is used.
Therefore, when LTE and business radio are interconnected on an IP network, an IP gateway for converting the business radio protocol to IP is required. In the Mission Critical Push to Talk (hereinafter referred to as MCPTT) system, for example, as described in the requirement specification of Non-Patent Document 4, the MCPTT application server also serves as a business radio IP gateway.

Next, each telephone number will be described.
In LTE, for example, as described in Non-Patent Document 1, a Mobile Station International Subscriber Directory Number (hereinafter referred to as MSISDN) in a USIM (Universal Subscriber Identity Module) is a telephone number.
MSISDN is structured as “country code + domestic destination number + subscriber number”.

On the other hand, in the case of business radio, the configuration method of the telephone number is different for each system. For example, in the case of ARIB STD T79 (Non-Patent Document 2), the system code (1 to 44 bits) + identifier (1 bit) + station number (19 bits) ). In the case of ARIB STD T102 (Non-patent Document 3), the manufacturer number (7 bits) is used.
Therefore, here, the telephone number of the business radio is referred to as “mobile station unique number”.

From the above, when an attempt is made to configure a dual mode mobile station of an LTE mobile station which is a wireless terminal and a business radio mobile station, there are two telephone numbers.
When individual communication is performed with a dual mode mobile station, normal individual communication can be performed by making a call to one of two telephone numbers.
However, 3GPP MCPTT over LTE and business radio have modes of simultaneous communication and group communication. In the case of simultaneous communication or group communication, voice communication is started without the receiving side going off-hook.

In addition, when a transmission is started by pressing PTT (Push to Talk) in simultaneous communication or group communication, the speaker is controlled so that the speaker is closed and no echo is generated.
The control method for closing the speaker is: (1) Recognizing that the mobile station itself is pressing PTT and closing the speaker from itself; (2) After pressing PTT, There are two possible ways of recognizing that is returning and closing the speaker.
In 1: N communication such as simultaneous communication and group communication, if N becomes large, the probability that many mobile stations push PTT all at once increases. Therefore, when N is large, "(2) After pressing PTT, the method of closing the speaker by recognizing that the receiver's sound is returning" will be dominant, and this method should be used. There are many.
The mobile station unique number is used to recognize that it is your own sound in the method of (2), and if the mobile station unique number of the received voice is yourself, the speaker is closed. Control is in progress. By performing such control, echoes are prevented from occurring in simultaneous communication or group communication.

When configuring a dual mode mobile station of LTE mobile station and business radio mobile station, there are two telephone numbers as described above, so when performing simultaneous communication or group communication, for example, press PTT on the business radio mobile station and talk When you start, you can hear your own voice from the LTE mobile station and echo. Also, when you start talking by pressing PTT at the LTE mobile station, you can hear your own voice from the business radio mobile station and an echo is generated.
Since MCPTT is implemented using Voice over IP (hereinafter referred to as VoIP), a FIFO (First-In First-Out) buffer is provided to absorb jitter on the IP network before returning to voice. Provide. This FIFO buffer delays audio. For this reason, an echo with a large delay amount may occur due to the delay of the network and the delay of the jitter absorbing buffer of VoIP.

  As a prior art document, for example, Patent Document 1 discloses an invention that prevents interference within a terminal in a dual-mode wireless terminal and prevents frequent handover to a cell in a narrow communication area.

JP 2009-284432 A

3GPP TS 23.003 V13.2.0 (2015-06) 3rd Generation Partnership Project; Technical Specification Group Core Network and Terminals; Numbering, addressing and identification (Release 13) 3 Numbering plan for mobile stations ARIB STD-T79 3.0, "Prefectural / Municipal Digital Mobile Communication System" (2.5.5 Mobile Station Identification Number), The Japan Radio Industry Association ARIB STD-T102 version 1.1, “Narrowband digital communication system (SCPC / 4-value FSK system)” (4.2.3.2 Manufacturer identification), Japan Radio Industry Association 3GPP TS 22.179 V13.2.0 (2015-06) 3rd Generation Partnership Project; Technical Specification Group Services and System Aspects; Mission Critical Push To Talk (MCPTT) over LTE; Stage 1 (Release 13) RFC 3261 SIP: Session Initiation Protocol ARIB STD-T61 1.2, “Narrowband Digital Communication System (SCPC / FDMA)”, The Japan Radio Industry Association

  An object of the present invention is a wireless communication system in which Mission Critical Push to Talk over LTE of 3rd Generation Partnership Project and other private wireless systems are interconnected over IP, and LTE mobile stations and mobile stations of other private wireless systems are connected. It is to realize simultaneous communication and group communication in which echo is not easily generated in a dual mode mobile station that is simultaneously supported.

  A radio communication system of the present invention is a radio communication system including an LTE network and a private wireless network connected by an IP network, and a dual mode mobile station that communicates with the LTE network and the private wireless network. The mobile station writes the mobile station unique number of the private radio in a predetermined area in the USIM, and when transmitting in the LTE mobile station mode, the mobile station unique number of the private radio in the USIM is used for the SIP-URI or SIPS-URI. When the private wireless network relays voice data from the LTE network to the private wireless network, it acquires the mobile station unique number from the SIP-URI or SIPS-URI indicating the transmission source of the LTE network, and relays the voice data to the private wireless network. It is characterized in that it is set as a sender number when

  In addition, when the dual mode mobile station receives the voice data in the private radio mobile station mode when transmitting in the LTE mobile station mode, the dual mode mobile station acquires the mobile station unique number from the voice data, and the mobile station unique number Is the unique number of the own station, it is preferable to suppress the output of the audio data from the speaker.

  The wireless communication system of the present invention is a wireless communication system including an LTE network and a private wireless network connected by an IP network, and a dual mode mobile station that communicates with the LTE network and the private wireless network. The dual mode mobile station writes the mobile station unique number of the private radio in a predetermined area in the USIM, and when transmitting in LTE mobile station mode, the mobile station unique number of the private radio in the USIM is added to the SIP-URI or SIPS-URI. When the private wireless network relays voice data from the private wireless network to the LTE network, put the mobile station unique number used in the private wireless network into the SIP-URI or SIPS-URI, A SIPS-URI is generated, the SIP-URI or SIPS-UPI is put in an area indicating a SIP transmission source, and voice data is relayed to the LTE network.

  Further, when the dual mode mobile station transmits the voice data in the LTE mobile station mode when transmitting in the private radio mobile station mode, the dual mode mobile station acquires the mobile station unique number from the voice data, and the mobile station unique number Is the unique number of the local station, it is preferable to close the LTE mobile station speaker.

  The wireless communication method of the present invention is a wireless communication method in which a mobile station performs wireless communication with an LTE network and a private wireless network. The LTE network and the private wireless network are connected by an IP network, and the mobile station is located in the USIM. When the mobile station unique number of the private radio is written in the MSISDN of the mobile station and the mobile station unique number of the private radio in USIM is used when transmitting in LTE mobile station mode, and when voice data is relayed from the LTE network to the private radio network Is characterized in that the mobile station unique number of the LTE network is acquired and set as the sender number when relaying to the private wireless network.

  Furthermore, the wireless communication method of the present invention is a wireless communication method in which a mobile station performs wireless communication with an LTE network and a private wireless network, wherein the LTE network and the private wireless network are connected by an IP network, and the mobile station performs LTE mobile communication. When transmitting in the station mode, the mobile station unique number of the private radio is used, and when the voice data is relayed from the private wireless network to the LTE network, the mobile station unique number used in the private wireless network is generated. Voice data is relayed in the LTE network.

  According to the present invention, in a dual mode mobile station in a wireless communication system in which MCPTT over LTE and a private wireless system are interconnected over IP, echoes can be prevented from being generated in simultaneous communication or group communication.

It is a figure which shows the outline | summary of a radio | wireless communications system. FIG. 6 is a diagram for explaining an operation of relaying voice data of the LTE network to the business radio network via the MCPTT application server of the radio communication system according to an embodiment of the present invention. FIG. 5 is a diagram for explaining an operation of relaying voice data of a business radio network to an LTE network via an MCPTT application server of a radio communication system according to an embodiment of the present invention. It is a sequence diagram for demonstrating operation | movement of the radio | wireless communications system which concerns on one Example of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing an outline of a wireless communication system.
In FIG. 1, a radio communication system 100 includes a Packet data network GateWay (hereinafter referred to as P-GW) 111, a Serving GateWay (hereinafter referred to as S-GW) 112, an eNB 113 which is an LTE radio base station, Policy and Charging. Rules Function (hereinafter referred to as PCRF) 114, Mobility Management Entity (hereinafter referred to as MME) 115, MCPPT Application Server 121, business radio base station 122, and mobile stations 131 and 132 which are radio terminals.
The P-GW 111 and MCPPT Application Server 121 are connected by the IP network 101.
The LTE network 110 includes P-GW111, S-GW112, eNB113, PCRF114, MME115, and the like.
The business radio network (private radio network) 120 includes an MCPPT Application Server 121, a business radio base station 122, and the like.
In FIG. 1, there are two mobile stations, but a plurality of mobile stations may be used.

The mobile station 131 and the mobile station 132 are mobile stations that support LTE mobile stations and commercial radio mobile stations at the same time, and can simultaneously transmit and receive signals to the LTE network (LTE network base station) and the commercial radio network (private communication system base station). It is a dual mode mobile station.
USIM is required for LTE mobile stations in dual mode mobile stations. Write the mobile station unique number of the business radio mobile station to the MSISDN in the USIM, and put the USIM in the LTE mobile station.

The S-GW 112 transfers the user packet transferred from the P-GW 111 to the eNB 113, and transfers the user packet transferred from the eNB 113 to the P-GW 111.
The MME 115 manages movement such as location registration, handover, and paging of the mobile station, and establishes and deletes bearers.
The P-GW111 serves as a connection point with an external network, and also has functions such as assignment of IP addresses to mobile stations and collection of billing data.
The PCRF 114 determines quality of service (hereinafter referred to as QoS) and charging for the user data packet.

The MCPTT application Server 121 is a server that performs a Mission Critical Push to talk service.
The service specifications of MCPTT over LTE are described in Non-Patent Document 4, and the chapter 4.5.3 MCPTT Users accessing the service through non-3GPP access interface is required to be able to connect to MCPTT from wireless systems other than 3GPP. . Therefore, the business radio is interconnected via the MCPTT application Server.

Next, an independent communication system will be described.
The private communication system is, for example, an ARIB STD-T61, ARIB STD-T79, or ARIB STD-T102 system that includes at least a base station and a plurality of mobile stations, and communicates with a predetermined radio system and signal format. is there. In the present invention, the self-operated communication system is not limited, and is a wireless communication system different from the public wireless system (LTE network in this embodiment), and includes a base station different from the public wireless system, and a predetermined wireless communication system. Any system may be used as long as communication is performed using a method and a signal format.

Next, how to use the mobile station unique number of business radio in MSISDN in USIM will be explained.
The SIP-URI, SIPS-URI, and From header field are described in Non-Patent Document 5.
In this embodiment, the mobile station unique number of the business radio mobile station is used for SIP-URI or SIPS-URI. Therefore, SIP-URI and SIPS-URI are as follows.
sip is a mobile station specific number @ domain name.
sips is a mobile station specific number @ domain name.

  For example, if the mobile radio unique number of the business radio mobile station is `` 01100155 '' and the domain name is `` xxxx.com '', the SIP-URI is sip: 01100155@xxxx.com, and when using the SIPS-URI, sips: 01100155@xxx.com

The originator in SIP is described in the From header field.
Therefore, when transmitting from the LTE mobile station to the MCPTT application server, the SIP-URI or SIPS-URL is entered in the From header field.
In the case of the above example, From: sip: 01100155@xxxx.com and From: sips: 01100155@xxxx.com.

Next, a method for relaying from the LTE network to the business radio network will be described with reference to FIG.
FIG. 2 is a diagram for explaining an operation of relaying voice data of the LTE network 110 to the business radio network 120 via the MCPTT application server of the radio communication system according to an embodiment of the present invention.

The mobile station unique number of the business radio mobile station of the mobile station 131 is “01100155”.
When PTT is pressed from an LTE mobile station, the SIP-URI is sip: 01100155@xxxx.com, and the voice data being pressed is delivered to the MCPTT application server 121 as From: sip: 01100155@xxxx.com.
From the SIP-URI in the From header field, the MCPTT application server 121 relays these audio data to the business radio network as the source audio 01100155.

The business radio mobile station of the mobile station 131 receives the voice data of the transmission source 01100155, but since 01100155 is itself, control is performed so as not to open the speaker of the business radio mobile station.
For this reason, since the voice data transmitted from the LTE mobile station is not output from the speaker of the business radio mobile station, no echo is generated.

Next, a method for relaying from the business radio network 120 to the LTE network 110 will be described with reference to FIG.
FIG. 3 is a diagram for explaining an operation of relaying voice data of the LTE network to the business radio network via the MCPTT application server of the radio communication system according to an embodiment of the present invention.
The mobile station unique number of the business radio mobile station of the mobile station 131 is “01100155”.
When the PTT is pressed from the business radio mobile station, the voice data having the transmission source 01100155 reaches the MCPTT application Server 121.

The MCPTT application server 121 sets SIP-URI as sip: 01100155@xxxx.com, sets From: sip: 01100155@xxxx.com in the From field of the SIP, and relays voice data to the LTE network.
The LTE mobile station of the mobile station 121 can recognize that it is receiving its own voice data because the SIP From field is sip: 01100155@xxxx.com. Control not to open.
For this reason, since the voice data transmitted from the business radio mobile station does not come out from the speaker of the LTE mobile station, no echo is generated.

Next, detailed operation of the wireless communication system according to the embodiment of the present invention will be described with reference to FIG.
FIG. 4 is a sequence diagram for explaining the operation of the radio communication system according to the embodiment of the present invention.
The unique numbers of the LTE mobile station and the business radio mobile station of the mobile station 131 are both “01100155”.

A case where the mobile station 131 transmits voice data in the LTE mobile station mode will be described with reference to FIGS.
2 and 4, the mobile station 131 transmits voice data to the LTE network 110 (403) when the PPT is pressed (402) in the LTE mobile station mode (401).
The LTE network 110 transmits voice data to the IP network 101 (404), the IP network 101 transmits voice data to the business radio network 120 (405), and the business radio network 120 transmits the voice data to the mobile station 131 ( 406).

  The mobile station 131 receives the voice data transmitted from the business radio network 120 (407), determines the unique number of the voice data transmission source, and if the unique number is its own station, the mobile radio station speaker. Is closed, and if the unique number is in another station, the speaker of the business radio mobile station is opened (408). In this control, the control unit of the mobile station 131 determines the unique number of the transmission source of the voice data received from the radio unit, and when the unique number is the own station, the business radio mobile connected to the control unit If the reception voice is not output from the station-side speaker and the specific number is not the local station, the reception voice is output from the speaker.

Next, the case where the mobile station 131 transmits voice data in the business radio mobile station mode will be described with reference to FIGS.
3 and 4, when the PPT is pressed (412) in the business radio mobile station mode (411), the mobile station 131 transmits voice data to the business radio network 120 (413).
The business radio network 120 transmits voice data to the IP network 101 (414), the IP network 101 transmits voice data to the LTE network 110 (415), and the LTE network 110 transmits the voice data to the mobile station 131 (416). ).

  The mobile station 131 receives the voice data transmitted from the LTE network 110 (417), determines the unique number of the voice data transmission source, and closes the LTE mobile station speaker if the unique number is its own station. When the unique number is in another station, the LTE mobile station speaker is opened (418). In this control, the control unit of the mobile station 131 determines the unique number of the transmission source of the voice data received from the radio unit, and when the unique number is the local station, the LTE mobile station connected to the control unit If the received sound is not output from the speaker on the side and the specific number is not the local station, the received sound is output from the speaker.

  The wireless communication system according to an embodiment of the present invention is a wireless communication system in which MCPTT over LTE and private wireless systems such as ARIB STD-T61, ARIB STD-T79, and ARIB STD-T102 are interconnected over IP, and are LTE mobile stations. And dual-mode mobile stations that simultaneously support business radio mobile stations such as ARIB STD-T61, ARIB STD-T79, and ARIB STD-T102, it is possible to prevent echoes from occurring in simultaneous communication or group communication.

Although one embodiment of the present invention has been described in detail above, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, in the above-described embodiment, a case has been described in which the dual mode mobile station includes two speakers, the LTE mobile station side speaker and the business radio mobile station side speaker. However, the dual mode mobile station in the present invention may be provided with a common speaker on the LTE mobile station side and the business radio mobile station side. Even in this case, the same effect as that of the above-described embodiment can be obtained.

  The dual mode mobile station can be applied to the use of determining whether or not the received voice data is the own station by setting the unique numbers of the two mobile stations to be the same.

  100: Wireless communication system, 101: IP network, 110: LTE network, 111: P-GW, 112: S-GW, 113: eNB, 114: PCRF, 115: MME, 120: Business wireless network, 121: MCPPT Application Server, 122: Business radio base station, 131, 132: Mobile station.

Claims (6)

A wireless communication system comprising an LTE network and a private wireless network connected by an IP network, and a dual mode mobile station that communicates with the LTE network and the private wireless network,
The dual mode mobile station writes the mobile station unique number of the private radio in a predetermined area in the USIM, and when transmitting in the LTE mobile station mode, the mobile station specific to the private radio in the USIM is transmitted to the SIP-URI or SIPS-URI. Use the number,
The private wireless network acquires the mobile station unique number from a SIP-URI or SIPS-URI indicating a transmission source of the LTE network when relaying voice data from the LTE network to the private wireless network, and the private wireless network A wireless communication system characterized by being set as a sender number when relaying voice data to a network. The wireless communication system according to claim 1, wherein
The dual mode mobile station acquires the mobile station unique number from the voice data when the voice data is received in the private radio mobile station mode when transmitting in the LTE mobile station mode. A wireless communication system, wherein when the number is a unique number of the own station, output of the audio data from a speaker is suppressed. A wireless communication system comprising an LTE network and a private wireless network connected by an IP network, and a dual mode mobile station that communicates with the LTE network and the private wireless network,
The dual mode mobile station writes the mobile station unique number of the private radio in a predetermined area in the USIM, and when transmitting in the LTE mobile station mode, the mobile station specific to the private radio in the USIM is transmitted to the SIP-URI or SIPS-URI. Use the number,
The private wireless network, when relaying voice data from the private wireless network to the LTE network, puts the mobile station unique number used in the private wireless network in SIP-URI or SIPS-URI, A wireless communication system, characterized in that a URI or SIPS-URI is generated, the SIP-URI or SIPS-UPI is placed in an area indicating a SIP transmission source, and voice data is relayed to the LTE network. The wireless communication system according to claim 3,
When the dual mode mobile station receives voice data in LTE mobile station mode when transmitting in the private radio mobile station mode, the dual mode mobile station acquires a mobile station unique number from the voice data, and the mobile station unique number A wireless communication system characterized by closing a speaker of an LTE mobile station when is a unique number of the local station. A wireless communication method in which a mobile station performs wireless communication with an LTE network and a private wireless network,
The LTE network and the private wireless network are connected by an IP network,
The mobile station writes the mobile station unique number of the private radio in the MSISDN in the USIM, and uses the mobile station unique number of the private radio in the USIM when transmitting in the LTE mobile station mode,
A radio station unique number is acquired when relaying voice data from the LTE network to a private wireless network, and set as a sender number when relaying to the private wireless network. Communication method. A wireless communication method in which a mobile station performs wireless communication with an LTE network and a private wireless network,
The LTE network and the private wireless network are connected by an IP network,
When the mobile station transmits in the LTE mobile station mode, the mobile station unique number of the private radio is used,
Radio communication characterized in that when voice data is relayed from the private wireless network to the LTE network, a mobile station unique number used in the private wireless network is generated and the voice data is relayed in the LTE network. Method.

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