JP2013016892A - User terminal and communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To covey an emergency message and regulation information to a user.SOLUTION: A user terminal for receiving emergency information includes: an emergency information reception determination unit for determining whether emergency information has been received; and a transmission control unit for controlling such that a keep-alive packet and user data is not transmitted when the emergency information has been received.

Description

  The present invention relates to a wireless communication system.

  It is required to construct an emergency information distribution platform as a quick and accurate information distribution means for natural disasters. In response to this demand, 3GPP (3rd Generation Partnership Project) has begun to investigate an emergency information distribution platform called “Public Warning System (PWS)”.

  In addition, “Earthquake and Tsunami Warning System (ETWS)” is defined in 3GPP (for example, see Non-Patent Document 1).

  The ETWS message is transmitted as broadcast information. Specifically, primary notification (Primary Notification) is transmitted as a warning type in a system information block (SIB) 10 of broadcast information. Further, secondary notification is transmitted as a warning message in the system information block 11 of the broadcast information.

  A user terminal that performs communication by a wireless communication method according to LTE (LTE: Long Term Evolution) receives system information block 10 and system information 11 after receiving paging. By receiving the system information block 10 and the system information 11, an ETWS message can be acquired.

  In other words, a user terminal that has a function (hereinafter referred to as “Always On”) that enables packet connection for packet communication at all times while in the network area, and the Always On function is on. If there is, the ETWS can be received even in the communication state (RRC_CONNECTED state).

3GPP TS22.168 V9.0.08 2008-06

  When an ETWS message is received in a state in which a voice call is being performed by a user terminal that performs communication by a wireless communication method according to the TL E, the user is notified simultaneously with the voice. In this case, it is difficult for the user to understand.

  In addition, a user terminal that performs communication using a wireless communication method according to UMTS (Universal Mobile Telecommunications System) can receive primary notification in an idle state, a CELL_PCH state, a URA_PCH state, and a CELL_FACH state. However, the user terminal cannot receive primary notification in the CELL_DCH state.

  Further, the user terminal cannot receive the secondary notification of ETWS in the CELL_FACH state and the CELL_DCH state.

  Further, the user terminal cannot receive information transmitted by the CBS (Cell Broadcast Service) method in the CELL_FACH state and the CELL_DCH state.

  That is, even if the user terminal is operating the always-on function, the ETWS message and the CBS message cannot be received in the CELL_DCH state.

  The present invention has been made in view of the above points, and an object of the present invention is to convey an emergency message or regulatory information to a user.

In order to solve the above problems, this user terminal
A user terminal that receives emergency information,
An emergency information reception determination unit that determines whether or not emergency information has been received;
When the emergency information reception determination unit determines that emergency information has been received, the transmission control unit is configured to have a transmission control unit that controls transmission of keep-alive packets and user data.

  When the state of the user terminal when the emergency information is received is any one of an idle state, a Cell_PCH state, and a URA_PCH state, the transmission control unit, until the reception of the emergency information is completed, By controlling so as not to perform the state transition to the Cell_DCH state, control may be performed so that any one of the keep-alive packet, user data, and system data is not transmitted.

  If the state of the user terminal when the emergency information is received is a Cell_FACH state, the state transition control unit controls to automatically transition to an idle state, thereby maintaining a keep alive packet, user data, The system data may be controlled not to be transmitted.

This user terminal
A user terminal that receives paging information,
A paging information reception determination unit that determines whether paging information has been received;
When it is determined that the paging information is received by the paging information reception determination unit, control is performed so that emergency information can be received when the state of the user terminal when the paging information is received is the Cell_DCH state. This is achieved as a user terminal having a state transition control unit.

This user terminal
A user terminal that receives emergency information,
An emergency information reception determination unit that determines whether or not emergency information has been received;
When it is determined that the emergency information is received by the emergency information reception determination unit and the user terminal is performing voice communication or data communication, the voice communication is interrupted and the emergency information is transmitted to the user by a voice message. This is achieved as a user terminal having an emergency information notification control unit that controls to notify the user.

  Moreover, it can also be comprised as a communication method which the said user terminal performs.

  According to the disclosed embodiment, the user can be notified of an emergency message or regulatory information.

It is a figure which shows one Example of a radio | wireless communications system. It is a figure which shows an example of the state of a user terminal. It is a figure which shows one Example of a user terminal. It is a functional block diagram which shows one Example of a user terminal. It is a functional block diagram which shows one Example of a user terminal. It is a sequence chart which shows an example of the delivery process of ETWS. It is a sequence chart which shows an example of the delivery process of CBS. It is a sequence chart (the 1) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 2) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 3) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 4) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 5) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 6) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 7) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 8) which shows one Example of operation | movement of a user terminal. It is a sequence chart (the 9) which shows one Example of operation | movement of a user terminal.

Next, the form for implementing this invention is demonstrated, referring drawings based on the following Examples.
In all the drawings for explaining the embodiments, the same reference numerals are used for those having the same function, and repeated explanation is omitted.

<Example>
<Wireless communication system>
FIG. 1 shows an embodiment of a wireless communication system.

  The environment to which the wireless communication system is applied may be an environment in which the first wireless communication system and the second wireless communication system overlap at least partially geographically. The first wireless communication system is assumed to be a third generation system such as the UTRA system. It is assumed that the second mobile communication system is an LTE system. However, applicable radio communication systems are not limited to LTE and UTRA systems, and may be other radio communication systems. For example, the present invention can be applied to a radio communication system of a system such as GERAN (GSM), CDMA2000, and UMTS, a fourth generation radio communication system, and the like. Specifically, the present invention can be applied to a wireless communication system in which an ETWS message and a CBS message are distributed and a user terminal can receive the ETWS message and the CBS message.

  FIG. 1 shows an example of an environment in which a first wireless communication system and a second wireless communication system are mixed.

The first wireless communication system (3G) includes a user terminal 100 _1, UTRA radio base station (Base Station) 200 _1, and a radio network controller 300.

UTRA radio base station 200 ₁ is connected to the radio network controller 300, the radio network controller 300 is connected to a core network 700. The UTRA radio base station 200 ₁ covers the cell 250 ₁ . The user terminal 100 ₁ performs radio communication with the UTRA radio base station 200 ₁ in the cell 250 ₁ using the UTRA scheme. UTRA radio base station 200 _1, the access point: may be referred to as (AP Access Point).

Figure 1 is a user terminal 100 ₁ one is illustrated, it may be two or more. Further, in FIG. 1, the UTRA radio base station 200 ₁ of the one in the radio network controller 300 is connected, may be two or more. Further, although one wireless network control device 300 is illustrated in FIG. 1, two or more wireless network control devices 300 may be provided.

The second mobile communication system includes a user terminal 100 _2, the LTE base station 200 _2, and MME400.

LTE base station 200 ₂ is connected to MME400 contained in the core network 700. The area covered by the LTE base station 200 ₂ includes a cell 250 _2. The area covered by the LTE base station 200 ₂ may include a plurality of cells. The plurality of cells may include cells capable of wireless communication in the same frequency band. A cell capable of wireless communication in the same frequency band may be referred to as a frequency layer. User terminal 100 ₂ perform wireless communication by LTE base station 200 ₂ and the Evolved UTRA and UTRAN scheme in the cell 250 _2.

LTE radio base station (eNB: eNodeB) 200 _2, not only the second wireless communication system (LTE), may perform the processing in the first wireless communication system (3G). LTE radio base station (eNB) 200 ₂ is in the second mobile communication system (LTE), for example, radio resource management, IP header compression and encryption processing, routing user plane data, scheduling, etc. paging message or broadcast information Do.

MME400 is coupled to LTE radio base station (eNB) 200 ₂ via the S1 interface. The MME 400 may be realized by a switching center. MME400 manages the movement of the user terminal 100 _2. Specifically, mobility management between 3GPP access networks, tracking area (location registration area) list management, packet data network (PDN) gateway (GW) selection, serving gateway (GW) selection, switching center for handover (MME) selection, roaming, authentication, radio access bearer management, subscriber information management, mobility management, outgoing / incoming control, charging control, QoS control, and the like are performed.

Although FIG. 1 one of the user terminal 100 ₂ is depicted, it may be two or more. Further, in FIG. 1 is MME400 to one LTE base station 200 ₂ is connected, LTE base station 200 ₂ of two or more may be connected. Further, although one MME 400 is illustrated in FIG. 1, two or more MMEs 400 may be provided.

  In addition, cells capable of wireless communication may be mixed using another wireless access technology different from the LTE method and the UTRA method. Such other radio access technologies may include GERAN (GSM), CDMA2000. Furthermore, a fourth generation mobile communication system may be included. The fourth generation mobile communication system may include LTE Advanced.

User terminal 100 ₂ can perform LTE radio base station 200 ₂ and the wireless communication may be one that can perform UTRA radio base station 200 ₁ both wireless communication. In other words, the user terminal 100 ₂ may be a dual mode terminal. The dual mode terminal can perform communication using an existing mobile communication system, for example, the UTRA system and the LTE system. Not only the user terminal 100 _2, information terminals, notebook PC, portable information terminals (PDA: Personal Digital Assistants) may include a communication device having a wireless communication function such as.

The user terminal 100 ₁ receives an ETWS message and a CBS message to be transmitted from the UTRA radio base station 200 ₁ .

  The ETWS message is transmitted as broadcast information. Specifically, the primary notification is transmitted as a warning type in the system information block 10 of broadcast information. The secondary notification is transmitted as a warning message in the system information block 11 of the broadcast information.

The transition ready by the user terminal 100 _1, and idle mode state, the Cell_PCH state, and URA_PCH state, the Cell_FACH state, includes a Cell_DCH state.

Figure 2 shows an example of a possible transition states by the user terminal 100 _1. A state that can be changed from a certain state is represented by an arrow.

2 shows, as a state possible transitions by the user terminal 100 _1, the idle state, Cell_DCH state, Cell_FACH state, Cell_PCH state, URA_PCH state is shown. States other than those shown here can also be set.

(Idle state)
If the user terminal 100 ₁ is idle, the dedicated physical channel is allocated. Respect to the user terminal 100 _first radio access network idle without any knowledge, not know even the existence position. The user terminal 100 _1, for detecting a call from the core network 700, the paging indicator channel for each DRX cycle (PICH: Paging Indicator CHannel) is monitored. The user terminal 100 _1, for receiving system information, monitors the BCH. The user terminal 100 _1, No uplink activity is possible. When the RRC connection is established, the state transitions from the idle state to the Cell_FACH state and the Cell_DCH state.

(Cell_DCH state)
If the user terminal 100 ₁ is Cell_DCH state, assigned dedicated physical channel uplink to downlink. The user terminal 100 _1, the cell level for the current active set is informed. The Cell_DCH state includes a transition from the idling state via RRC connection setup and a transition from the Cell_FACH state due to establishment of a dedicated physical channel.

(Cell_FACH state)
If the user terminal 100 ₁ is Cell_FACH state, the user terminal 100 ₁ is dedicated physical channel is allocated. The user terminal 100 ₁ monitors the FACH channel in the downlink. The user terminal 100 ₁ is the default common transport channel or a shared transport channel is allocated to the uplink. Specifically, RACH is assigned. According to the access procedure to the user terminal 100 ₁ transport channel may be used at any time. Location of the user terminal 100 _1, the user terminal 100 ₁ is at the cell level according to the cell where the cell was last updated is notified by UTRAN.

(Cell_PCH state)
If the user terminal 100 ₁ is Cell_PCH state, the user terminal 100 ₁ is dedicated physical channel is allocated. The user terminal 100 ₁ in order to detect a call from the core network 700 monitors a PICH every DRX cycle. The user terminal 100 _1, for receiving system information, monitors the BCH. The user terminal 100 _1, No uplink activity is possible. Location of the user terminal 100 ₁ is in Cell_FACH state, the user terminal 100 ₁ is at the cell level according to the cell where the cell was last updated is notified by the UTRAN.

(URA_PCH state)
If the user terminal 100 ₁ is URA_PCH state, the user terminal 100 ₁ is dedicated physical channel is allocated. The user terminal 100 _1, for detecting the reading from the core network 700 monitors a PICH every DRX cycle. User terminal 100 _1, for receiving system information, monitors the BCH. The user terminal 100 _1, No uplink activity is possible. Location of the user terminal 100 ₁ is in Cell_FACH state, the user terminal 100 ₁ is at the cell level according to the cell where the cell was last updated is notified by the UTRAN.

User terminal 100 ₁ is idle, Cell_PCH, in URA_PCH state can be received ETWS message, the CBS message. The user terminal 100 _1, while receiving ETWS message, the CBS message is controlled so as not to transmit keep-alive packets, user data. Specifically, the user terminal 100 _1, Cell_FACH state, the Cell_DCH state controlled not to transition. Cell_FACH state, by the Cell_DCH state controlled not to transition, the user terminal 100 ₁ may receive ETWS message, a CBS message to the end.

The user terminal 100 ₁ is the Cell_FACH state, when receiving the primary Notification silicic Deployment, transitions to the idle state. By transition to the idle state, the user terminal 100 _1, it is possible to receive a secondary Notification silicic Deployment can receive the ETWS to the end.

Further, UTRA radio base station 200 _1, the user terminal Cell_DCH state, may be transmitted paging type 2 (Paging Type2) message. Paging Type 2 message may be received even the user terminal 100 ₁ of Cell_DCH state. Paging Type 2 message, by sending the primary Notification silicic Deployment, the user terminal 100 ₁ may be a Cell_DCH state can receive primary Notification silicic Deployment.

  Further, the keep-alive with always-on may be executed in the Cell_FACH state. Further, the keep alive packet may be transmitted on a common channel.

<User terminal>
FIG. 3 shows an embodiment of the user terminal 100 ₁ and the user terminal 100 ₂ . FIG. 3 mainly shows the hardware configuration.

The user terminal 100 ₁ and the user terminal 100 ₂ include an input unit 102, an output unit 104, a communication control unit 106, a radio unit 108, a storage unit 110, and a central processing unit (CPU) 112. Have Each functional block is connected by a bus 150.

The user terminal 100 ₁ and the user terminal 100 ₂ may be any appropriate terminal with which the user can communicate, and include, for example, a mobile phone, an information terminal, a personal digital assistant, a portable personal computer, and the like. Not.

  The central processing unit 112 controls the input unit 102, output unit 104, communication control unit 106, radio unit 108, and storage unit 110. The central processing unit 112 functions according to a program stored in the storage unit 110 and performs predetermined processing.

The storage unit 110 includes an application and an operating system (OS: Operating System). The application is software having a function of executing a work executed by the user on the user terminal 100 ₁ and the user terminal 100 ₂ . The operating system is software that provides application software with an interface that abstracts hardware in the user terminal 100 ₁ and the user terminal 100 ₂ .

The input unit 102 includes, for example, a keyboard and a mouse, and is a device for inputting instructions and data to the user terminal 100 ₁ and the user terminal 100 ₂ . Moreover, you may be comprised with a touchscreen. In addition, the input unit 102 is configured by a microphone, for example, and inputs a voice uttered by the user. The voice may include instructions to the user terminal 100 ₁ and the user terminal 100 ₂ . The instruction includes an instruction for an operating system and an application.

The output unit 104 includes, for example, a display, and displays a processing state and a processing result by the user terminal 100 ₁ and the user terminal 100 ₂ . Further, the output unit 104 may be configured by a speaker, for example, and may output sound to the user. The processing state and the processing result include those according to the operating system and applications. The display includes a liquid crystal display (LCD), a CRT (Cathode Ray Tube) display, a plasma display (PDP), an organic EL (Electro-Luminescence) display, and the like.

The communication control unit 106 generates an uplink signal to the network to which the user terminal 100 is connected. Further, the communication control unit 106 analyzes downlink signals from the base stations (UTRA radio base station 200 ₁ , LTE radio base station 200 ₂ ) connected to the user terminal 100.

The radio unit 108 performs radio communication with the LTE radio base station 200 ₁ and the UTRA radio base station 200 ₂ by a predetermined radio communication scheme under the control of the central processing unit 112. The wireless communication system includes GSM and W-CDMA. LTE may also be included. For example, the control information generated by the communication control unit 106 is converted into a radio signal and transmitted. Also converts the radio signal from the LTE base station ₂₀₀ 1, UTRA radio base station 200 ₂ into a baseband signal.

<User terminal 100 ₁ of function>
The functions performed by the user terminal 100 _1, ETWS message, if it is being received CBS message, the keepalive packet includes the ability to control so as not to transmit the user data. Specifically, when the state at the time of receiving the ETWS message and the CBS message is an idle state, a function of controlling so as not to transition to the Cell_FACH state and the Cell_DCH state is included. That is, in the state transition diagram shown in FIG. 2, when the state when the ETWS message and the CBS message are received is an idle state, control is performed so as not to transition the state. By controlling so as not to change the state, the keep-alive packet and user data are not transmitted.

Also, the functions performed by the user terminal 100 _1, ETWS message, Cell_PCH state when receiving the CBS message, if it is URA_PCH state, the ability to control not to transition to the Cell_FACH state included. By controlling so as not to transit to the Cell_FACH state, the keep-alive packet and user data are not transmitted.

Also, the functions performed by the user terminal 100 _1, when the state when receiving the primary Notification silicic Deployment should be included in the ETWS message is a Cell_FACH state, the control to transition to the idle state Functions to be included. By performing control so as to transition to the idle state, the secondary notification can be received.

Also, the functions performed by the user terminal 100 _1, when the state when receiving the paging type 2 message is a Cell_DCH state includes the ability to control to receive the primary Notification silicic Deployment. By sending a paging type 2 message, it is possible to receive the primary Notification silicic Deployment to the user terminal 100 _1.

Also, the functions performed by the user terminal 100 _1, Keepalives allways on include the ability to control to run in Cell_FACH state. This is because the primary notification can be received by being executed in the Cell_FACH state. User terminal 100 ₁ receives the primary Notification silicic Deployment can receive secondary Notification silicic Deployment by transition to the idle state.

Need not have all of the all of the functions described above with the user terminal 100 _1, it may be one having at least one function.

Figure 4 shows a functional block diagram of one embodiment of a user terminal 100 _1. The user terminal 100 ₂ is a dual terminal, even when the functions according to the UTRA scheme, the functions shown in FIG. 4 is executed. FIG. 4 mainly shows functions executed by the central processing unit 112.

User terminal 100 ₁ includes an emergency information reception determining unit 1122, and a transmission control unit 1124.

The emergency information reception determining unit 1122 determines on the user terminal 100 _1, ETWS message, whether CBS message is received. When it is determined that an ETWS message or a CBS message has been received, the emergency information reception determination unit 1122 inputs information indicating the type of emergency information together with information indicating that emergency information has been received to the transmission control unit 1124. To do. The information indicating the type of emergency information includes information indicating primary notification and secondary notification that should be included in the ETWS message. The information indicating the type of emergency information includes information indicating CBS.

The transmission control unit 1124 is connected to the emergency information reception determination unit 1122. Transmission control section 1124, if the information indicating that the emergency information from the emergency information reception determining unit 1122 has been received is inputted from the user terminal 100 _1, keep-alive packets, user data controlled not sent .

Transmission control unit 1124 detects the state of the user terminal 100 ₁ when the information indicating that the emergency information from the emergency information reception determining unit 1122 has been received is inputted.

Transmission control section 1124, the state of the user terminal 100 ₁ is when it is determined that the idle state, Cell_FACH state, the Cell_DCH state controlled not to transition. That is, control is performed so that state transition is not performed.

Transmission control section 1124, the state of the user terminal 100 ₁ is Cell_PCH, when it is determined that the URA_PCH state, the Cell_FACH state controlled not to transition. That is, control is performed so that state transition is not performed.

When information indicating that emergency information has been received from the emergency information reception determination unit 1122 is input, the transmission control unit 1124 receives information indicating primary notification as information indicating the type of emergency information. when it is, the state of the user terminal 100 ₁ is when it is determined that the Cell_FACH state is controlled to transition to the idle state.

Further, the transmission control unit 1124, a paging type 2 message to the user terminal 100 ₁ as it is received, information indicating that the paging type 2 message was received is input. Transmission control unit 1124, when the information indicating that a paging type 2 message is received is input, when the state of the user terminal 100 ₁ is determined to be Cell_DCH state, the primary Notification silicic Deployment The wireless unit 108 is instructed to receive. The primary notification can be received with the reception of a paging type 2 message as a trigger.

  Also, the transmission control unit 1124 performs control so that keep-alive with always-on is executed in the Cell_FACH state.

<Functions of the user terminal 100 _2>
The functions performed by the user terminal 100 _2, during a voice communication by the LTE scheme, when the ETWS is received, includes the ability to automatically disconnect the audio. Data communication may be in progress.

Also, the functions performed by the user terminal 100 _2, to interrupt the voice communication, it includes the ability to retrieve information ETWS.

Also, the functions performed by the user terminal 100 _2, after acquiring the information of the ETWS, include the ability to sound an alarm.

Also, the functions performed by the user terminal 100 ₂ includes a function of notifying the information of ETWS. Specifically, it is notified by a voice message.

Also, the functions performed by the user terminal 100 ₂ includes a function to resume the voice call was interrupted.

Figure 5 shows a functional block diagram of one embodiment of a user terminal 100 _2. FIG. 5 mainly shows functions executed by the central processing unit 112.

User terminal 100 ₂ includes an emergency information reception determining section 1122, and emergency information notification control unit 1126.

The emergency information reception determining unit 1122 determines on the user terminal 100 _2, ETWS message, whether CBS message is received. When the emergency information reception determination unit 1122 determines that an ETWS message or a CBS message has been received, the emergency information reception determination unit 1122 inputs information indicating that emergency information has been received to the emergency information notification control unit 1126. Information indicating the type of emergency information may be input. For example, information indicating primary notification and secondary notification to be included in the ETWS message may be input. Further, for example, information indicating CBS may be input.

The emergency information notification control unit 1126 is connected to the emergency information reception determination unit 1122. Emergency information notification control unit 1126, when the information indicating that the emergency information from the emergency information receiver detection unit 1122 has been received is inputted, determines the state of the user terminal 100 _1. Specifically, the emergency information notification control unit 1126 determines whether voice communication is being performed by the user terminal 100 _1. When it is determined that voice communication is being performed, the emergency information notification control unit 1126 inputs a voice communication control signal for controlling the voice communication by the input unit 102 and the output unit 104 to be interrupted. The emergency information notification control unit 1126 performs control to acquire ETWS information. The emergency information notification control unit 1126 performs control to notify the ETWS information from the output unit 104. Specifically, ETWS information is notified as the received sound. The emergency information notification control unit 1126 inputs a voice communication control signal for resuming voice communication.

<ETWS message delivery processing>
FIG. 6 shows an example of ETWS message distribution processing.

  Information necessary for distributing emergency information is exchanged between a cell broadcast entity (CBE) and a cell broadcast center (CBC) (step S602). Specifically, information representing the type of disaster and information representing the distribution area are exchanged.

  The CBC creates an ETWS message (step S604).

  The CBC creates an ETWS CBS based on information from the CBE. The CBC notifies the RNC 300 of the ETWS CBS as a Write-Replace (step S606). The Write-Replace includes a Paging ETWS Indicator, a Warning Type, and a Warning-Security-Information. A message ID for ETWS may be used as the message ID.

The RNC 300 operates as an ETWS when the Paging ETWS Indicator is included in the Write-Replace from the CBC. That is, ETWS is distributed. RNC300, when functioning as ETWS, the user terminal 100 _1, is updated on the CTCH (Commom traffic channel).

  The RNC 300 transmits paging (step S608). The paging may be used to notify that the broadcast information has been updated and WarningType. Also, Duplication detection may be performed by paging. The RNC 300 may transmit a primary notification together with paging.

  The RNC 300 transmits the secondary notification (step S610). The RNC 300 may transmit the BMC CBS message together with the secondary notification.

  The RNC 300 transmits a Write-Replace Complete to the CSC (step S612).

<CBS message distribution processing>
FIG. 7 shows a CBS message distribution process.

  The RNC 300 is notified of emergency information, specifically information indicating that an earthquake or the like has occurred (step S702).

RNC300 is a UTRA radio base station 200 ₁ reports the system information block modifier (step S704).

The UTRA radio base station 200 ₁ notifies system information to the user terminal 100 ₁ (step S706). The system information block includes information indicating that the CTCH is opened.

RNC300 is the user terminal 100 ₁ transmits a paging type 1 (step S 708).

The user terminal 100 _1, to open the CTCH.

RNC300 is the user terminal 100 ₁ transmits a CBS message (step S710).

RNC300 is a UTRA radio base station 200 ₁ reports the system information block modifier (step S712).

The UTRA radio base station 200 ₁ notifies the system information to the user terminal 100 ₁ (step S714). The system information block includes information indicating that the CTCH is closed.

RNC300 is the user terminal 100 ₁ transmits a paging type 1 (step S716).

User terminal 100 ₁ closes the CTCH.

<Operation of user terminal (1)>
Figure 8 illustrates user terminal 100 ₁ of operation (Part 1). FIG. 8 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_FACH state.

User terminal 100 _1, the network sends a measurement report (Measurement Report) (step S802).

Network, the user terminal 100 ₁ transmits a transport channel reconfiguration (Transport Channel Reconfiguration) (step S804).

User terminal 100 _1, the network transmits a transport channel reconfiguration complete (Transport Channel Reconfiguration Complete) (step S806).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (2)>
9, the user terminal 100 ₁ of operation (Part 2) showing. FIG. 9 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_FACH state.

From the network, the user terminal 100 _1, system information change indication (System Information Change Indication (ETWS) ) is transmitted (step S902).

User terminal 100 _1, the network sends a measurement report (step S904).

Network, the user terminal 100 ₁ transmits a transport channel reconfiguration (step S906).

User terminal 100 _1, the network transmits a transport channel reconfiguration complete (step S908).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (part 3)>
Figure 10 illustrates a user terminal 100 ₁ of operation (Part 3). FIG. 10 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_PCH state.

User terminal 100 ₁ transmits to the network, the cell update (Cell Update) (step S1002).

Network, the user terminal 100 ₁ transmits a Cell Update Confirm (Cell Update Confirm) (step S1004).

User terminal 100 _1, the network sends the wireless bare slurry Configuration Complete (step S1006).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (4)>
Figure 11 illustrates the user terminal 100 ₁ of operation (Part 4). FIG. 11 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_PCH state.

From the network, the user terminal 100 _1, the paging type 1 (Paging Type1 (ETWS)) is transmitted (step S1102).

Here, the user regardless of whether operating the user terminal 100 _1, the user terminal 100 _1, after receiving the Primary Notification silicic Deployment does not transmit a fixed time. The user terminal 100 _1, after a said predetermined time, receiving a secondary Notification silicic Deployment.

User terminal 100 _1, the network sends a cell update (step S1104).

Network, the user terminal 100 ₁ transmits a Cell Update Confirm (step S1106).

The user terminal 100 ₁ of Cell_PCH state, the network transmits a radio bare slurry Configuration Complete (step S1108).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (5)>
Figure 12 illustrates a user terminal 100 ₁ of operation (Part 5). FIG. 12 mainly illustrates processing executed by the transmission control unit 1124.

User terminal 100 ₁ is idle.

User terminal 100 _1, the network sends a RRC connection request (RRC Connection Request) (step S1202).

Network, the user terminal 100 ₁ transmits an RRC connection setup (Setup) (step S1204).

User terminal 100 _1, the network sends the wireless bare slurry Configuration Complete (step S1206).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (6)>
FIG. 13 shows the operation ( _No. 6) of the user terminal 1001. FIG. 13 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is idle.

Network, the user terminal 100 ₁ transmits a paging type 1 (ETWS) (step S1302).

Here, the user regardless of whether operating the user terminal 100 _1, the user terminal 100 _1, after receiving the Primary Notification silicic Deployment does not transmit a fixed time. The user terminal 100 _1, after a said predetermined time, receiving a secondary Notification silicic Deployment.

User terminal 100 _1, the network sends a RRC connection request (step S1304).

Network, the user terminal 100 ₁ transmits an RRC connection setup (step S1306).

User terminal 100 _1, the network sends the wireless bare slurry Configuration Complete (step S1308).

User terminal 100 ₁ makes a transition to Cell_DCH state.

<Operation of user terminal (7)>
Figure 14 illustrates a user terminal 100 ₁ of operation (Part 7). FIG. 14 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_PCH state.

User terminal 100 _1, the network sends a cell update (step S1402).

Network, the user terminal 100 ₁ transmits a Cell Update Confirm (step S1404).

User terminal 100 _1, the network sends a UTRAN Mobility Information Confirm (Utran Mobility Information Confirm) (step S1406).

User terminal 100 ₁ makes a transition to Cell_FACH state.

<Operation of user terminal (8)>
FIG. 15 shows an operation ( _No. 8) of the user terminal 1001. FIG. 15 mainly shows processing executed by the transmission control unit 1124.

User terminal 100 ₁ is a Cell_PCH state.

From the network, the user terminal 100 _1, the paging type 1 (ETWS) is transmitted (step S1502).

Here, the user regardless of whether operating the user terminal 100 _1, the user terminal 100 _1, after receiving the Primary Notification silicic Deployment does not transmit a fixed time. The user terminal 100 _1, after a said predetermined time, receiving a secondary Notification silicic Deployment.

User terminal 100 _1, the network sends a cell update (step S1504).

Network, the user terminal 100 ₁ transmits a Cell Update Confirm (step S1506).

User terminal 100 _1, the network sends a Utran mobility Information Confirm (step S1508).

User terminal 100 ₁ makes a transition to Cell_FACH state.

<Operation of User Terminal 100 ₁ ( _No. 9)>
Figure 16 shows an embodiment of the operation of the user terminal 100 _1. FIG. 16 shows the keep-alive operation with always-on. When the keep alive operation is performed, the transmission control unit 1124 performs control so that the operation is performed in the Cell_FACH state.

16, the radio access network: The (RAN Radio Access Network), a UTRA radio base station 200 _1, includes a radio network controller 300.

The operating system installed in the user terminal 100 _1, the instruction to transmit the keep-alive packet to the user terminal 100 ₁ of the radio unit 108 is performed (step S1602). The command for transmitting the keep-alive packet is performed in a cycle T, for example. The instruction by the operating system may be referred to as a supervisor call (SVC).

User terminal 100 _1, according to a transmission instruction of the keep-alive packets from OS, transmits an activate packet data protocol context request (Activate PDP (Packet Data Protol) Context Request) to the core network 700 (step S1604). Between the user terminal 100 ₁ and the core network 700, non-communication monitoring timer t is started (step S1606).

User terminal 100 ₁ transmits a RAN, signaling connection release indication to (Signaling Connection Release Indication (Fast Dormancy )) ( step S1608).

The core network 700, when the no-communication monitor timer t expires, the user terminal 100 ₁ transmits a deactivation packet data protocol context request (Deactivate PDP Context Request) (step S1610).

By the deactivate packet data protocol context request, allways on the trigger it is generated in the user terminal 100 ₁ (step S1612).

User terminal 100 ₁ transmits an activate packet data protocol context request to the core network (step S1614). User terminal 100 ₁ transmits signaling connection release indication to (Signaling Connection Release Indication (Fast Dormancy )) in RAN (step S1616).

From OS, the instruction to transmit the keep-alive packet to the user terminal 100 ₁ of the radio unit 108 is performed (step S1618).

User terminal 100 ₁ in accordance with the keep-alive packet transmission instruction from the OS, for transmitting data, and transmits RRC connection request (RRC Connection Request) to the RAN (step S1620). Between the user terminal 100 ₁ and the core network 700, non-communication monitoring timer t is started (step S1622).

User terminal 100 ₁ transmits to the core network 700, signaling connection release indication to (Signaling Connection Release Indication (FastDormancy) ) ( step S1624).

The core network 700, when the no-communication monitor timer t expires, the user terminal 100 ₁ transmits a deactivation packet data protocol context request (step S1626).

By the deactivate packet data protocol context request, allways on the trigger it is generated in the user terminal 100 ₁ (step S1628).

User terminal 100 ₁ transmits an activate packet data protocol context request to the core network (step S1630). User terminal 100 _1, the RAN, sending a signaling connection release indication (step S 1632).

From OS, the instruction to transmit the keep-alive packet to the user terminal 100 ₁ of the radio unit 108 is performed (step S1634).

  According to the present embodiment, it is possible to control the 3G system so as not to transmit / receive keep-alive packets, user data, and system data in the always-on connection while receiving the earthquake early warning.

  Specifically, the transition from the idle state, the Cell_PCH state, and the URA_PCH state to the CEll_FACH state and the Cell_DCH state is not performed during reception of the primary notification that should be included in the ETWS message and for a certain period after reception. To be controlled.

  Further, the transition from the Cell_FACH state to the Cell_DCH state is controlled not to be performed during reception of the primary notification that should be included in the ETWS message.

  Further, according to the present embodiment, it is possible to transmit call information that enables the reception of the earthquake early warning to the communicating user terminal. By doing in this way, even in the user terminal in the Cell_DCH state, information for receiving the primary notification to be included in the ETWS message by paging that can receive the primary notification to be included in the ETWS message Can be sent.

  Also, according to the present embodiment, when an earthquake early warning is transmitted during voice communication, the voice can be disconnected and an alarm for the emergency earthquake early warning can be sounded. Specifically, when an earthquake early warning is transmitted during voice communication, the voice is pending, an emergency earthquake early warning alarm is sounded, the voice is concealed, and after the alarm is sounded, the voice is resumed.

  Further, according to the present embodiment, when an earthquake early warning is transmitted during voice communication or data communication, it can be notified by a voice message. Alarms may sound before and after voice messages.

  In addition, according to the present embodiment, it is possible to transmit and receive keep-alive packets and system data in a constant connection on a common channel.

  For convenience of explanation, specific numerical examples will be described to facilitate understanding of the invention. However, unless otherwise specified, these numerical values are merely examples, and any appropriate value may be used.

  Although the present invention has been described above with reference to specific embodiments, each embodiment is merely an example, and those skilled in the art will understand various variations, modifications, alternatives, substitutions, and the like. I will. For convenience of explanation, an apparatus according to an embodiment of the present invention has been described using a functional block diagram, but such an apparatus may be realized by hardware, software, or a combination thereof. The present invention is not limited to the above-described embodiments, and various variations, modifications, alternatives, substitutions, and the like are included without departing from the spirit of the present invention.

100 ₁ 100 ₂ User mobile 200 ₁ UTRA radio base station 200 ₂ LTE radio base station 250 ₁ , 250 ₂ cells 300 Radio network controller 400 MME
DESCRIPTION OF SYMBOLS 102 Input part 104 Output part 106 Communication control part 108 Radio | wireless part 110 Storage part 112 Central processing unit 1122 Emergency information reception determination part 1124 Transmission control part 1126 Emergency information notification control part

Claims (6)

A user terminal that receives emergency information,
An emergency information reception determination unit that determines whether or not emergency information has been received;
A transmission control unit configured to control transmission of keep-alive packets and user data when it is determined by the emergency information reception determination unit that emergency information has been received. The user terminal according to claim 1,
When the state of the user terminal when the emergency information is received is any one of an idle state, a Cell_PCH state, and a URA_PCH state, the transmission control unit, until the reception of the emergency information is completed, A user terminal that performs control so as not to perform a state transition to the Cell_DCH state, so that any one of keep-alive packets, user data, and system data is not transmitted. The user terminal according to claim 1,
If the state of the user terminal when the emergency information is received is a Cell_FACH state, the state transition control unit controls to automatically transition to an idle state, thereby maintaining a keep alive packet, user data, And a user terminal that controls not to transmit any of the system data. A user terminal that receives paging information,
A paging information reception determination unit that determines whether paging information has been received;
When it is determined that the paging information is received by the paging information reception determination unit, control is performed so that emergency information can be received when the state of the user terminal when the paging information is received is the Cell_DCH state. A user terminal having a state transition control unit. A communication method in a user terminal that receives emergency information,
An emergency information reception determination step for determining whether emergency information has been received; and
And a transmission control step for controlling the transmission of keep-alive packets and user data when it is determined that the emergency information is received by the emergency information reception determination step. A user terminal that receives emergency information,
An emergency information reception determination unit that determines whether or not emergency information has been received;
When it is determined that the emergency information is received by the emergency information reception determination unit and the user terminal is performing voice communication or data communication, the voice communication is interrupted and the emergency information is transmitted to the user by a voice message. And an emergency information notification control unit that controls to notify the user terminal.

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