JP6227275B2 - Mobile communication terminal and mobile communication method - Google Patents

Description

  The present invention relates to a mobile communication terminal and a mobile communication method.

  In 3GPP, a Long Term Evolution (LTE) standard, which is a further development of a communication method called third generation, is created, and a service conforming to the standard is provided. The LTE standard specifies a method for determining whether to switch to a new cell from a cell that is currently located when a mobile station exists at the boundary between cells provided by two or more base stations. Yes.

  In Non-Patent Documents 1 and 2, when the number of cell transitions exceeds a certain value within a certain time, the mobile device is in a medium or high-speed movement state (Medium-mobility or High-mobility). A method for changing the parameters used to determine the cell transition is defined. The mobile device can smoothly transition to neighboring cells by determining cell transition using appropriate parameters for each moving speed.

  Further, Patent Documents 1 and 2 disclose information on a specific cell (CSG cell: Closed Subscriber Group cell) in order to reduce the number of times of cell reselection for the purpose of reducing power consumption of a terminal related to cell reselection. The invention to be used is disclosed. Patent Documents 3 and 4 disclose inventions that manage cell history data and share terminal device information between access nodes in order to detect frequent movement between cells.

JP 2012-109640 A JP 2011-87294 A Special table 2011-511488 gazette Special table 2010-517341

3GPP Technical Specification TS36.304 3GPP Technical Specification TS36.331

  However, in the conventional method, even when moving at a low speed at a cell boundary or the like, based on the number of cell transitions, the moving state is regarded as high speed or medium speed, and unnecessary handover occurs. There was a possibility. As a result, there is a possibility that the throughput of the mobile device is reduced and the battery life is deteriorated.

  The present invention has been made in view of the above problems, and an object of the present invention is to perform an appropriate handover according to a moving state.

In order to solve the above problems, a mobile communication terminal according to an embodiment of the present invention is provided.
A mobile communication terminal,
A communication unit that communicates with an external system;
A receiving unit that receives information indicating that the moving speed of the mobile communication terminal changes from the external system;
In response to the reception of the information, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the neighboring cell is, the ranking reference value of the neighboring cell is currently being communicated. A selection unit for selecting a parameter used for selection of a base station to be connected, so that a threshold value compared with a time exceeding the ranking reference value of the cell of
A determining unit that determines one base station to be connected from two or more base stations using the selected parameter;
Have

The mobile communication method in one embodiment of the present invention is as follows.
A mobile communication method executed by a mobile communication terminal,
A communication stage to communicate with an external system;
Receiving from the external system information indicating that the moving speed of the mobile communication terminal changes; and
In response to receiving the information, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the mobile communication terminal is, the ranking reference value of the neighboring cell used for determining the selection of the neighboring cell is the ranking of the cell currently in communication A selection step for selecting a parameter used for selection of a base station to be connected so that a threshold value compared with a time exceeding a reference value is small ;
Using the selected parameter to determine a base station to be connected from two or more base stations;
Have

  According to an embodiment of the present invention, an appropriate handover is performed according to the movement state.

The figure which shows the radio | wireless communications system which concerns on one Embodiment of this invention. The figure which shows a mode that the mobile apparatus which concerns on one Embodiment of this invention communicates with a ticket gate. The hardware block diagram of the mobile apparatus which concerns on one Embodiment of this invention. The figure which shows the functional block of the moving apparatus (1st Embodiment) which concerns on one Embodiment of this invention. The figure which shows the flow of a process of the moving apparatus (1st Embodiment) which concerns on one Embodiment of this invention. The figure which shows the operation example of the radio | wireless communications system (1st Embodiment) which concerns on one Embodiment of this invention. The figure which shows the functional block of the moving apparatus (2nd Embodiment) which concerns on one Embodiment of this invention. The figure which shows the flow of a process of the moving apparatus (2nd Embodiment) which concerns on one Embodiment of this invention. The figure which shows the operation example of the radio | wireless communications system (2nd Embodiment) which concerns on one Embodiment of this invention. The figure for demonstrating the parameter selected according to the kind of ticket gate and entry / exit information. The figure which shows the functional block of the moving apparatus (3rd Embodiment) which concerns on one Embodiment of this invention. The figure which shows the flow of a process of the moving apparatus (3rd Embodiment) which concerns on one Embodiment of this invention. The figure which shows the operation example of the radio | wireless communications system (3rd Embodiment) which concerns on one Embodiment of this invention. The figure for demonstrating the parameter selected according to boarding ticket information.

  Embodiments will be described below with reference to the accompanying drawings. In the figures, similar elements are given the same reference numbers or reference signs.

1. 1. Overview of wireless communication system 2. Hardware configuration 3. Functions of mobile device in the first embodiment 4. Operation example of mobile device in first embodiment Second embodiment
function
Example of operation Third embodiment
function
Example of operation

≪ １． Overview of wireless communication system ≫
FIG. 1 is a schematic diagram of a wireless communication system 1 according to the present embodiment. As shown in FIG. 1, the wireless communication system 1 includes a mobile device 100, a core network 200, an E-UTRAN 300, and sectors 410 and 420.

  The core network 200 includes a packet switch 210 for E-UTRAN, a circuit switch 220, and a packet switch 230 for UTRAN (not shown). The packet switch 210 for E-UTRAN stores packets transmitted from the E-UTRAN 300, so-called LTE network, and distributes and transmits the transmission destinations based on destination information indicated by the packets. The circuit switch 220 mainly performs a voice call, so selects a physical communication path between the mobile devices and connects the mobile devices. The packet switch 230 for UTRAN accumulates packets transmitted from UTRAN, a so-called conventional 3G network, and transmits the packets based on destination information indicated by the packets.

  The E-UTRAN 300 is a network corresponding to the LTE standard standardized by 3GPP. In FIG. 1, two base stations 310 and 320 (also called E-UTRAN NodeB) are illustrated. Base stations 310 and 320 cover sectors 410 and 420 as areas where communication signals with mobile device 100 can be transmitted and received, respectively. Base station 310 covers cell 415 in sector 410 with a predetermined carrier frequency, and base station 420 covers cell 425 in sector 420.

  The mobile device 100 is a mobile communication terminal such as a data communication terminal used by being connected to a mobile phone, a smart phone, a PC, or the like, and a base station using E-UTRA, which is a radio access technology defined by 3GPP. Communicate with. In FIG. 1, the mobile device 100 belongs to a cell 415 and can communicate with a base station 310 that covers the cell 415. In order to reselect a cell (base station) with better conditions even when the mobile device 100 is located in one cell, the mobile device 100 selects the currently communicating cell and adjacent cells based on the radio quality. Ranked. The following is a formula for ranking that is defined in 3GPP.

R _s = Q _{meas, s} + Q _Hyst (1)
R _n = Q _{MEAS, N} + Q _offset (2)
R _s : Ranking reference value of the currently communicating cell (“Cell-ranking Criterion”)
R _n : Ranking reference value of adjacent cell Q _meas : RSRP (Reference Signal Received Power) measurement amount, or
RSRQ (Reference Signal Received Quality) measurement amount Q _hyst : Hysteresis value Q _offset : Offset value The mobile device 100 determines the ranking reference value of the cell currently in communication as the ranking reference value of an adjacent cell for a predetermined time ( If it is above (represented by the “T _{reselectionEUTRA} ” value), _reselect its neighboring cells. Here, as the values of “Q _hyst ” and “T _{reselectionEUTRA} ” are smaller, adjacent cells are more easily _reselected .

  Further, for example, when the mobile device 100 leaves the cell 415 covered by the base station 310 and moves to the cell 425 covered by the base station 320 (arrow in FIG. 1) during data communication, the communication state is maintained. The base station to be connected can be switched to the base station 320. Such processing is generally called handover. Handover conditions and methods are defined in 3GPP. Hereinafter, a method in which the base station determines to execute handover based on an event that has occurred in the mobile device 100 will be described.

  The mobile device 300 measures the quality of radio signals transmitted from the communicating base station 310 and the adjacent base station (for example, the base station 320) as needed under the control of the communicating base station 310. When the quality satisfies a predetermined condition, the result is transmitted to the base station 310 as a report. The predetermined condition is defined for each type of event defined by 3GPP. For example, in 3GPP, “Event 3A” generated by the following equation is defined as one of the conditions for handing over from a base station in the area to an adjacent base station.

Mn + Ofn + Ocn-Hys> Mp + Ofp + Ocp + Off Formula (3)
Mn: Radio quality of neighboring cell (RSRP measurement amount or RSRQ measurement amount)
Ofn: Frequency-specific offset value of neighboring cell Ofn: Cell-specific offset value of neighboring cell Hys: Hysteresis parameter Mp: Radio quality (RSRP measurement amount or RSRQ measurement amount) of the currently communicating cell
Off: Frequency-specific offset value of the cell currently being communicated Ocp: Offset value specific to the cell currently being communicated Off: Offset value for the event (a3-Offset)
Note that 3GPP defines events such as “Event A1” to “Event A5” and “Event B1” to “Event B2” in addition to “Event 3A” described above. Hereinafter, description will be made using the above-described example of “Event 3A”.

  When the mobile device 100 detects that the above equation (3) continues to be satisfied for a certain period of time (represented by the “timeToTrigger” value), the mobile device 100 transmits the result to the base station 310. Receiving this, the base station 310 determines to execute the handover, and instructs the mobile device 100 and the adjacent base station 320 to perform the handover. Thereafter, the mobile device 100 switches the connection from the base station 310 to the adjacent base station 320, performs synchronization processing, etc., and then enables data communication through the base station 320. Here, among the values defined by the above formula, the smaller the Hys, Off, and timeToTrigger values, the easier the handover is performed.

Here, the mobile device 100 can change the parameters related to the cell reselection or handover described above according to its own moving speed, and can perform control so that the cell reselection or handover can be easily performed. Such processing is defined as “Speed dependent scaling” in 3GPP. Specifically, the mobile device 100 indicates that the number of cell transitions (handover or cell selection) is represented by a predetermined number (“N _{CR_H} ” value) within a certain time (represented by a “T _CRmax ” value). If it exceeds ")", the movement speed is considered to be high (Hign-mobility). In addition, the mobile device 100 has a medium speed (Medium-mobility) when the number of cell transitions exceeds a predetermined number (represented by the “N _{CR_M} ” value) within a certain time T _CRmax . ). Then, the mobile device 100 changes the values of the parameters Q _hyst, T _{reselectionEUTRA} , and timeToTrigger according to the respective moving speeds, so that the mobile device 100 can transition to an adjacent cell more quickly.

  Here, the mobile device 100 includes an RFIC (Radio Frequency Integrated Circuit), and controls the processing related to “Speed dependent scaling” described above according to communication from the ticket gate 500 installed in a railway station, a passage, or the like. can do. FIG. 2 shows a state in which the mobile device 100 has passed through the railway ticket gate 500. The mobile device 100 and the ticket checker 500 can communicate according to standards such as Felica (registered trademark), which is a communication method for non-contact type IC cards, and NFC (Near Field Communication), which is a higher standard, for example. . As described above, the RFIC of the mobile device 100 receives the entrance / exit information to the premises of the railway station by communicating with the ticket gate 500. The mobile device 100 controls the processing related to “Speed dependent scaling” described above according to the communication content.

  As will be described in detail later, in one embodiment of the present invention, when the mobile device 100 receives the entrance information (hereinafter referred to as “entrance information”) after passing through the ticket gate 500, the above-described “Speed dependent scaling” is performed. Enable such processing. This is because when moving on a railway, there is a high possibility that the moving speed is high or medium, and agile cell transition is required. On the other hand, when the mobile device 100 passes the ticket gate 500 and receives exit information (hereinafter referred to as “exit information”), the mobile device 100 invalidates the processing related to “Speed dependent scaling” described above. Thereby, although the mobile device 100 is not moving at high speed or medium speed, it is possible to reduce the possibility of cell transition. As described above, in one embodiment of the present invention, the entrance information and the exit information are used as information representing a change in the moving speed of the mobile device 100.

  In the following, description will be given using an example in which the mobile device 100 receives information from the ticket gate 500 installed at the railway station via the RFIC. However, the mobile device 100 may receive information via radio waves from, for example, an ETC (Electronic Tool Collection System) gate installed at an interchange on a highway or another external system.

≪ 2. Hardware configuration ≫
FIG. 3 illustrates an example of a hardware configuration of the mobile device 100 according to an embodiment of the present invention. FIG. 3 illustrates a hardware configuration example when the mobile device 100 is a smartphone. The mobile device 100 includes a CPU 11, a RAM 12, a ROM 13, a communication module 14 and an antenna 15, an RFIC module 16 and an antenna 17, a GPS reception module 18 and an antenna 19, an acceleration sensor 20, a display 21, and a touch panel 22. A microphone 23, a speaker 24, and a battery 25.

  The CPU 11 executes a program that controls the operation of the mobile device 100. The RAM 12 constitutes a work area of the CPU 11 and the like. The ROM 13 stores a program executed by the CPU 11 and data necessary for executing the program. The communication module 14 is a communication device for connecting to E-UTRAN. The antenna 15 is one or more antennas corresponding to the communication module 14.

  The RFIC module 16 and its antenna 17 are devices for communicating with an IC card reader / writer provided in the ticket gate 500 in accordance with Felica (registered trademark), NFC (Near Field Communication) or other IC card communication standards. . The RFIC module 16 further includes an area where user data can be stored. The GPS receiving module 18 and its antenna 19 are devices for receiving a positioning signal transmitted from a GPS satellite and measuring the current position of the mobile device 100. The acceleration sensor 20 is a device that detects a change in acceleration of the mobile device 100 in the x, y, and z axis directions.

  The display 21 is a device for presenting a screen to the user. The touch panel 22 is a device that receives input from a user. The microphone 23 converts the user's voice into an electrical signal. The speaker 24 outputs an electrical signal as sound. The battery 25 is a device that supplies electric power for driving the mobile device 100. The bus 26 connects the above-described devices except for the battery 25 to each other.

  When the mobile device 100 is a data terminal or the like connected to a PC, the GPS receiving module 18 and its antenna 19, the acceleration sensor 20, the display 21, the touch panel 22, the microphone 23, and the speaker 24 shown in FIG. The battery 25 may not be provided.

≪ 3. Functions of the mobile device in the first embodiment >>
FIG. 4 is a functional block diagram of the mobile device 100 according to the first embodiment of the present invention. Hereinafter, portions related to the present invention will be mainly described. Therefore, it should be noted that the mobile device 100 includes a block (power supply unit or the like) that is not shown in the figure or omitted in the description, which is essential for realizing the function as the mobile device 100.

  As illustrated in FIG. 4, the mobile device 100 includes a wireless reception unit 101, a wireless transmission unit 102, a connection control unit 103, a parameter selection unit 104, a non-contact communication unit 105, a detection unit 106, and a switching unit. 107, a first storage unit 150, and a second storage unit 170. In the following, first, the information stored in the first storage unit 150 and the second storage unit 170 will be described, and then the details of each functional unit will be described.

  The first storage unit 150 is realized by the ROM 13 in FIG. 3 and stores cell transition information 151 and adjustment parameter information 152.

  The cell transition information 151 includes information indicating the history of cell transition and is updated every time a cell transition is made. The cell transition information 151 is mainly used for determining the moving speed of the mobile device 100.

The adjustment parameter information 152 includes adjustment parameter information that is added or multiplied according to the moving speed with _respect to Q _hyst or T _{reselectionEUTRA} that determines the ease of cell _reselection . Tunable, in the 3GPP standard, is defined as "sf-High" and "sf-Medium", for both Q _hyst and T _{ReselectionEUTRA,} are prepared, respectively. In other words, when the movement state is represented by “high speed”, “medium speed”, or other speed (hereinafter referred to as “normal”), the values of Q _hyst and T _{reselectionEUTRA} are updated as follows: Is done.
_-High speed Q _hyst = Q _hyst + sf-High (for Q _hyst ) ・ ・ ・ Formula (4)
T _{reselectionEUTRA} = T _{reselectionEUTRA} x sf-High (for T _{reselectionEUTRA} ) (5)
_-Medium speed Q _hyst = Q _hyst + sf-Medium (for Q _hyst ) Formula (6)
T _{reselectionEUTRA} = T _{reselectionEUTRA} x sf-Medium (for T _{reselectionEUTRA} ) Formula (7)
_-Normal Q _hyst (the value is used as it is) ... Formula (8)
T _{reselectionEUTRA} (The value is used as is) ・ ・ ・ Expression (9)
The adjustment parameter information 152 may include information on timeToTrigger (unit: millisecond) selected according to the moving speed (high speed, medium speed, normal). As the value of timeToTrigger, a smaller value is selected for a higher moving speed.

  In one embodiment, the following adjustment parameters may be used in any combination together with timeToTrigger or instead of timeToTrigger.

<Adjustment parameters used for cell reselection>
-Qoffset: A smaller value is selected for a higher moving speed.-Thresh _{Serving, LowP} : Srxlev (reception level value for cell selection) threshold when reselecting a cell of a network with a lower priority. A larger value is selected for a higher moving speed—Thresh _{Serving, LowQ} : A _Squal (cell selection quality value) threshold for reselecting a cell of a network with a lower priority. Larger values are selected for higher travel speeds—Thresh _{X, HighP} : Srxlev threshold for reselecting cells of higher priority networks. Smaller values are selected for higher travel speeds—Thresh _{X, HighQ} : _Squal threshold for reselecting cells of higher priority networks. Smaller values are selected for higher travel speeds—Thresh _{X, LowP} : Srxlev threshold for reselecting cells of lower priority networks. Smaller values are selected for higher moving speeds—Thresh _{X, LowQ} : _Squal threshold for reselecting cells in lower priority networks. For higher movement speeds, smaller values are selected

<Adjustment parameters used for handover>
-Hys: A smaller value is selected for a higher moving speed-Off (a3-Offset): A smaller value is selected for a higher moving speed

<Adjustment parameters used for cell reselection (UTRAN → E-UTRAN)>
Thresh _{Serving, LowP} , Thresh _{Serving, LowQ} : Srxlev threshold and Squal threshold when reselecting a cell of a network with a lower priority. For higher movement speeds, a larger value is selected-Thresh _{X, high} , Thresh _{X, high2} , Thresh _{X, low} , Thresh _{X, low2} : _Select a cell with a higher or lower priority network Srxlev threshold and Squal threshold for reselection. For higher movement speeds, smaller values are selected

<Adjustment parameters used for handover (UTRAN → E-UTRAN, Event3a)>
-H _3a : Hysteresis parameter for event 3a. For higher travel speeds, a smaller value is selected-Q _Used : Quality estimate of the used UTRAN frequency. For higher movement speeds, a larger value is selected -M _OtherRAT : Measured amount of cells in other systems. For higher movement speeds, smaller values are selected

  For events such as “Event A1” to “Event A5”, “Event B1”, and “Event B2”, a smaller timeToTrigger, Hys (hysteresis value), and ReportInterval (report interval) are selected for higher movement speeds. May be.

Further, the threshold parameters may be selected as follows for events such as “Event A1” to “Event A5”, “Event B1”, and “Event B2”, respectively.
-Event A1: Lower Thresh is selected for higher movement speeds-Event A2: Higher Thresh is selected for higher movement speeds-Event A4: For higher movement speeds Lower Thresh is selected-Event A5: Higher Thresh1 and lower Thresh2 are selected for higher movement speeds-Event B1: Lower Thresh is selected for higher movement speeds -Event B2: A higher Thresh1 and a lower Thresh2 are selected for a higher moving speed In the following embodiment, an explanation will be given using an example in which the timeToTrigger value of "Event 3A" is selected.

  The second storage unit 170 is realized by a ROM (not shown) in the RFIC module 16 of FIG. 3 and stores the entrance / exit information 171. The entrance / exit information 171 includes the entrance / exit information of the ticket gate written by the ticket gate 500, and as illustrated in FIG. 2, information such as the station name (identifier) of the station that entered or exited, the time of entry / exit, the fare including. In addition to the entrance / exit information 171, the second storage unit 170 may include an identifier unique to the RFIC module 16 and balance information of electronic money.

  The wireless reception unit 101 and the wireless transmission unit 102 are realized mainly by the processing of the communication module 14, the antenna 15, and the CPU 11, and provide a communication interface for communicating with the base station.

  The connection control unit 103 is realized mainly by the processing of the CPU 11. The connection control unit 103 uses the radio quality information received by the radio reception unit 101 and the adjustment parameter information selected by the parameter selection unit 104 to perform an event related to cell selection / reselection and handover (for example, , “Event 3A”) described above is detected.

The connection control unit 103 performs cell reselection by ranking the cells. Cell ranking is performed according to the above-mentioned formulas (1) and (2). Here, for the values of Q _hyst and T _{reselectionEUTRA} used in equations (1) and (2) for ranking, updated values are used according to the adjustment parameter selected by the parameter selection unit 104 (equation (4)). -See equation (9)).

  Further, when the above equation (3) is satisfied by the timeToTrigger time selected by the parameter selection unit 104, the connection control unit 103 reports to the base station that “Event 3A” has occurred.

  In this way, the connection control unit 103 plays a role as a determination unit that determines a cell (base station) to be connected and a report generation unit (report) that generates a report according to event detection and transmits the report to the base station. As a transmitter).

  Further, the connection control unit 103 can perform synchronization processing and reconnection processing necessary for handover in accordance with an instruction from the base station.

  Note that details of procedures related to cell selection / reselection, event detection related to handover, transmission of a report related to the event, and the like are stipulated in 3GPP, and thus description thereof is omitted here.

  In addition, if the parameter selection unit 104 (to be described later) determines that the movement speed is “high speed” or “medium speed”, the connection control unit 103 prepares for both the currently communicating cell and the adjacent cell. One of the thresholds that define the conditions for generating an event may be ignored. Examples of events having such a threshold include “Event A5”, “Event B2”, and “Evernt 3A”. When the moving speed is “high speed” or “medium speed”, the connection control unit 103 can improve the ease of transition by ignoring one of the threshold values that are the conditions for the occurrence of these events. .

The parameter selection unit 104 is realized mainly by the processing of the CPU 11 and uses the cell transition information 151 stored in the first storage unit 150 to determine the current moving speed of the mobile device 100 and select the corresponding adjustment parameter. To do. The relationship between the moving speed and the selected adjustment parameter is as follows.
_-High speed: sf-High (for Q _hyst ), sf-High (for T _{reselectionEUTRA} ), timeToTrigger (high speed)
_-Medium speed: sf-Medium (for Q _hyst ), sf-Medium (for T _{reselectionEUTRA} ), timeToTrigger (medium speed)
- Normal: TimeToTrigger (Normal) (modification to Q _hyst and T _{ReselectionEUTRA} is not performed)
Here, the parameter selection unit 104 determines the moving speed of the mobile device 100 based on the number of cell transitions within a certain time T _CRmax . Specifically, the parameter selection unit 104 determines that the moving speed is “high speed” when the number of cell transitions exceeds a predetermined number N _{CR_H} . Further, the parameter selection unit 104 determines that the moving speed is “medium speed” when the number of cell transitions exceeds a predetermined number N _{CR_M} .

  When the movement speed is determined, the parameter selection unit 104 refers to the adjustment parameter information 152 of the first storage unit 150 and selects an adjustment parameter corresponding to each movement speed. Then, the parameter selection unit 104 passes the selected adjustment parameter to the connection control unit 103.

As will be described in detail later, the parameter selection unit 104 determines that the moving speed is high or medium only when receiving an instruction from the switching unit 107, and selects different adjustment parameters according to the moving speed. it can. On the other hand, when no instruction is received from the switching unit 107, the adjustment parameter is selected assuming that the moving speed is “normal” regardless of the moving speed. That is, when the moving speed is “normal”, the corresponding timeToTrigger value is selected, and the correction value for Q _hyst and T _{reselectionEUTRA} is not selected (or 0 as the correction parameter for Q _hyst and the correction parameter for T _{reselectionEUTRA} 1 may be selected).

  As described above, any adjustment parameter other than timeToTrigger may be selected by the parameter selection unit 104.

  The non-contact communication unit 105 is mainly realized by the RFIC module 16 and the antenna 17, reads a signal transmitted from the ticket checker 500, and writes entrance / exit information as entrance / exit information 171 of the second storage unit 170. When entering the inside of the ticket gate of the station, the non-contact communication unit 105 receives entrance information (name of the station that entered the station, time, etc.) and writes the information as entrance / exit information 171. Further, when the contactless communication unit 105 goes outside the ticket gate of the station, the contactless communication unit 105 receives exit information (name of the station that left the station, time, etc.) and writes the information as entrance / exit information 171.

  The detection unit 106 is realized mainly by the processing of the CPU 11 and detects communication with the ticket gate 500 by the non-contact communication unit 105. The detection unit 106 detects that the non-contact communication unit 105 has received entrance information or exit information, and notifies the switching unit 107 to that effect.

  When the switching unit 107 is realized mainly by the processing of the CPU 11 and receives notification that the entrance information has been received from the detection unit 106, the switching unit 107 determines that the moving speed is high speed or medium speed to the parameter selection unit 104, An instruction is given to select a different adjustment parameter according to the result. In other words, the switching unit 107 switches the mode of the parameter selection unit 104 so as to enable Speed dependent scaling by adjustment parameter selection. Accordingly, the connection control unit 103 performs cell reselection and handover using different parameters according to the moving speed.

  On the other hand, upon receiving notification from the detection unit 106 that the exit information has been received, the switching unit 107 selects, in the parameter selection unit 104, an adjustment parameter when the movement speed is “normal” regardless of the movement speed. Instruct. In other words, the switching unit 107 switches the mode of the parameter selection unit 104 so as to invalidate Speed dependent scaling due to adjustment parameter selection. Accordingly, the connection control unit 103 performs cell reselection and handover based on the same parameter regardless of the moving speed.

  With the above function, the mobile device 100 according to the embodiment of the present invention determines that the moving state is “high speed” or “medium speed” when entering the inside of the ticket gate of the railway station, and responds accordingly. Cell transition can be performed. On the other hand, when leaving the ticket gate outside the railway station, the movement state is not determined as “high speed” or “medium speed”, and the possibility of inadvertent cell transition is reduced.

<< 4. Example of operation of mobile device in first embodiment >>
Next, operation examples of the mobile device 100 and the wireless communication system 1 according to the first embodiment of the present invention will be described using FIG. 5 and FIG.

  FIG. 5 is a diagram illustrating a processing flow of the mobile device 100 according to the first embodiment of the present invention.

  First, when the detection unit 106 detects that the entrance information has been received from the ticket gate 500 (Yes in step S101), the switching unit 107 selects a different adjustment parameter depending on the moving speed with respect to the parameter selection unit 104. (That is, Speed dependent scaling is enabled) (step S102). Otherwise, the process returns to step S101 again.

Next, the parameter selection unit 104 refers to the cell transition information 151 in the first storage unit 150, and when the number of cell transitions within a certain time T _CRmax exceeds a certain value N _{CR_H} (Yes in step S103). ), An adjustment parameter (high speed) is selected, and the adjustment parameter is passed to the connection control unit 103 (step S104). Otherwise, the process proceeds to step S105.

Next, the parameter selection unit 104 refers to the cell transition information 151 in the first storage unit 150, and when the number of cell transitions within a certain time T _CRmax exceeds a certain value N _{CR_M} (Yes in step S105). ), An adjustment parameter (medium speed) is selected, and the adjustment parameter is passed to the connection control unit 103 (step S106). Otherwise, the parameter selection unit 104 selects an adjustment parameter (normal) and passes the adjustment parameter to the connection control unit 103.

  Next, when the detection unit 106 detects that the exit information has been received from the ticket checker 500 (Yes in step S108), the switching unit 107 determines whether or not the parameter selection unit 104 has a moving speed regardless of the moving speed. An instruction is given to select an adjustment parameter for “normal” (that is, Speed dependent scaling is disabled) (step S109). Otherwise, the process returns to step S103.

  By the above processing, the speed dependent scaling is switched between valid / invalid according to the entrance / exit of the ticket gate 500, and cell selection and handover are frequently performed in the area outside the ticket gate where movement at high speed is not expected. Can be hard to break. As a result, throughput reduction of the mobile device 100 and battery consumption due to unnecessary cell transition can be suppressed.

  FIG. 6 is a sequence diagram illustrating an operation example of the wireless communication system 1 according to the first embodiment of the present invention. In FIG. 6, descriptions of connection establishment and disconnection sequences, a sequence for executing a handover, and the like performed between the mobile device 100 and the base station or the core network are omitted.

  First, the connection control unit 103 of the mobile device 100 establishes a connection with the base station 310 through a cell selection procedure defined by 3GPP (step S201), and cell transition information 151 stored in the first storage unit 150. Is updated (step S202).

  Next, the non-contact communication unit 105 of the mobile device 100 receives the entry information from the ticket gate 500, and writes the information as the entry / exit information 171 in the second storage unit 170 (step S203). Here, as described above, the function of Speed dependent scaling is enabled, and an adjustment parameter corresponding to the moving speed of the mobile device is selected.

  Thereafter, it is assumed that the connection control unit 103 establishes a connection with the base station 320 as the mobile device 100 moves (step S204). The connection control unit 103 updates the transition information 151 (step S205).

Here, it is assumed that the parameter selection unit 104 of the mobile device 100 detects that the number of cell transitions within a certain time T _CRmax exceeds a certain value N _{CR_H} with reference to the cell transition information 151. The parameter selection unit 104 selects an adjustment parameter (high speed) and passes the adjustment parameter to the connection control unit 103 (step S206). During this time, it is assumed that data communication is performed between the mobile device 100 and the base station 320.

  The connection control unit 103 of the mobile device 100 evaluates the expression (3) using the received adjustment parameter, and detects “Event 3A” (step S207). Then, the connection control unit 103 transmits a report to the base station 320 (step S208).

  Receiving the report, the base station 320 determines that the mobile device 100 executes handover to the base station 330 and instructs the mobile device 100 to execute processing related to handover (not shown). In response to an instruction from the base station 320, the connection control unit 103 of the mobile device 100 executes processing related to the handover to the base station 330 and connects to the base station 330 (step S209).

  Thereafter, the non-contact communication unit 105 of the mobile device 100 receives the exit information from the ticket gate 500, and writes the information as the entrance / exit information 171 in the second storage unit 170 (step S210). Here, as described above, the function of Speed dependent scaling is disabled, and an adjustment parameter corresponding to the moving speed of the mobile device is selected.

  As described above, in the wireless communication system 1 according to the first embodiment of the present invention, the speed dependent scaling function for controlling the frequency of cell transition is switched between valid / invalid according to the entrance / exit of the ticket gate. As a result, the mobile device 100 can increase the frequency of cell transition only during high-speed movement using the railway, and inadvertently during movement at a normal movement speed, such as when walking without using the railway. Cell transition is not performed. As a result, there is an advantage that the throughput reduction of the mobile device 100 and the battery consumption can be suppressed.

<< 5. Second Embodiment >>
Next, the mobile device 100A and the wireless communication system 1A according to the second embodiment of the present invention will be described with reference to FIGS. In the present embodiment, the mobile device 100A receives entrance / exit information from two types of ticket gates 500A and 500B installed at a railway station. The ticket gate 500A is a ticket gate for a high-speed railway represented by a Shinkansen. The ticket gate 500B is a ticket gate for a normal railway represented by a conventional line. Hereinafter, in order to compare a ticket gate for a normal railway with a ticket gate for a high-speed rail, it will be called an ordinary rail. Note that the hardware configuration of the mobile device 100A is the same as the hardware configuration of the mobile device 100 as shown in FIG.

≪Function≫
First, the function of the mobile device 100A in the second embodiment of the present invention will be described with reference to FIG.

  The non-contact communication unit 101 of the mobile device 100A receives the entrance / exit information from the two types of ticket gates 500A, 500B and stores the entrance / exit information as the entrance / exit information 171 in the second storage unit 170.

  The detection unit 103A of the mobile device 100A detects that the non-contact communication unit 101 has received the entrance / exit information from the two types of ticket gates 500A and 500B, and notifies the parameter selection unit 104A to that effect.

  When the detection unit 103A detects the entry / exit information from the ticket gate, the parameter selection unit 104A of the mobile device 100A selects the adjustment parameter stored in the adjustment parameter information 152 of the first storage unit 150, and the selected adjustment The parameter is passed to the connection control unit 103A. FIG. 10 shows the relationship with the adjustment parameter selected according to the contents of the entrance / exit information detected by the detection unit 103A.

  As shown in FIG. 10, upon receiving entrance information from the ticket gate 500A (ticket gate for high-speed railway), the parameter selection unit 104A selects an adjustment parameter (high speed). Also, the parameter selection unit 104A selects the adjustment parameter (medium speed) when receiving the entrance information from the ticket gate 500B (ordinary railway ticket gate).

  Here, when exit information is received from the ticket gate 500A (ticket gate for high-speed railway), an adjustment parameter (medium speed) or an adjustment parameter (normal) is selected. This is because the adjustment parameter (medium speed) is selected when “exit” from the ticket gate 500A and at the same time “entrance” from the ticket gate 500B, and when “exit” directly from the ticket gate 500A to the outside. This indicates that the adjustment parameter (normal) is selected.

  The connection control unit 103A of the mobile device 100A always uses the adjustment parameter received from the parameter selection unit 104A to perform ranking for cell reselection and event detection for handover regardless of the procedure of Speed dependent scaling. Do.

  With the above function, the mobile device 100A according to the embodiment of the present invention reduces the frequency of cell transition when high-speed movement by rail is not assumed, while the inside of the ticket gate of the railroad, according to the speed of the railroad, Cell reselection or handover can be performed to facilitate cell transition.

≪ Example of operation ≫
Next, operation examples of the mobile device 100A and the wireless communication system 1A according to the second embodiment of the present invention will be described with reference to FIGS.

  FIG. 8 is a diagram illustrating a processing flow of the mobile device 100A according to the second embodiment of the present invention.

  First, when the detection unit 103A detects that the entrance information has been received from the ticket gate 500A (high speed railway ticket gate) (Yes in step S301), the parameter selection unit 104A selects an adjustment parameter (high speed) ( Step S302). Otherwise, the process proceeds to step S306, and an adjustment parameter (medium speed) is selected.

  Subsequent to step S302, if the entrance information is received from the ticket gate 500B (ordinary railway ticket gate) (the exit information is simultaneously received from the ticket gate 500A) (Yes in step S303), the process proceeds to step S306. Then, the parameter selection unit 104A selects an adjustment parameter (medium speed) (step S306).

  On the other hand, when the detection unit 103A does not receive the entrance information from the ticket gate B (No in Step S303) and receives the exit information from the ticket gate 500A (Yes in Step S304) following the step S302, the adjustment parameter (Normal) is selected (step S305), and the process ends. If the exit information is not received from the ticket gate 500A, the process returns to step S303.

  After the adjustment parameter (medium speed) is selected in step S306, when the detecting unit 103A receives the entrance information from the ticket gate 500A (Yes in step S307), the process returns to step S302, and the adjustment parameter (high speed) is selected. To do.

  On the other hand, when the detection unit 103A does not receive the entrance information from the ticket gate 500A (No in Step S307) and also receives the exit information from the ticket gate 500B (Yes in Step S304), the adjustment parameter (normal) is selected. (Step S305), the process ends. If the exit information is not received from the ticket gate 500B, the process returns to step S307.

  Through the above processing, the mobile device 100A can control the ease of cell transition for each moving means having different moving speeds, such as a Shinkansen and a conventional line. As a result, smooth cell transitions are realized when using mobile means, while throughput is reduced due to unnecessary cell transitions by suppressing cell transitions when high-speed mobile means are not used. Can be prevented.

  FIG. 9 is a sequence diagram illustrating an operation example of the wireless communication system 1A according to the second embodiment of the present invention. In FIG. 9, descriptions of connection establishment and disconnection sequences, a sequence for executing a handover, and the like performed between the mobile device 100A and the base station or the core network are omitted.

  First, the connection control unit 103A of the mobile device 100A establishes a connection with the base station 310 through a cell selection procedure defined by 3GPP (step S401). Next, the non-contact communication unit 105 of the mobile device 100B receives the entrance information from the ticket gate 500A (the ticket gate for high-speed railway), and writes the information as the entrance / exit information 171 in the second storage unit 170 (step) S402). Also, the parameter selection unit 104A of the mobile device 100A selects an adjustment parameter (high speed) and passes the adjustment parameter to the connection control unit 103A (step S403).

  Next, the connection control unit 103A of the mobile device 100A evaluates the expression (3) using the received adjustment parameter, and detects “Event 3A” (step S404). Then, the connection control unit 103A transmits a report to the base station 310 (step S405). Receiving the report, the base station 310 determines that the mobile device 100A executes handover to the base station 320, and instructs the mobile device 100A to execute processing related to handover (not shown). In response to an instruction from the base station 310, the connection control unit 103A of the mobile device 100A executes processing related to the handover to the base station 320 and connects to the base station 320 (step S406).

  Next, the non-contact communication unit 105 of the mobile device 100A receives exit information from the ticket gate 500A (ticket gate for high-speed rail) (step S407), and at the same time, entrance information from the ticket gate 500B (ticket gate for ordinary railroad). Is received (step S408). Then, the parameter selection unit 104A of the mobile device 100A selects the adjustment parameter (medium speed), and passes the adjustment parameter to the connection control unit 103A (step S409).

  Next, the connection control unit 103A of the mobile device 100A evaluates the expression (3) using the received adjustment parameter, and detects “Event 3A” again (step S410). Then, the connection control unit 103A transmits a report to the base station 320 (step S411). Receiving the report, the base station 320 determines that the mobile device 100A executes handover to the base station 330 and instructs the mobile device 100A to execute processing related to handover (not shown). In response to an instruction from the base station 320, the connection control unit 103A of the mobile device 100A executes processing related to the handover to the base station 330 and connects to the base station 330 (step S412).

  Thereafter, the non-contact communication unit 105 of the mobile device 100A receives exit information from the ticket gate device 500B (step S413). Then, the parameter selection unit 104A of the mobile device 100A selects the adjustment parameter (normal) and passes the adjustment parameter to the connection control unit 103A (step S414).

  As described above, in the wireless communication system 1A according to the second embodiment of the present invention, the frequency of cell transition of a mobile device can be changed according to the speed of a moving means such as a Shinkansen or a conventional line. On the other hand, when the moving means is not used, the parameter is selected so as to suppress the frequency of cell transition of the mobile device. As a result, inadvertent cell transition of the mobile device is suppressed, and a decrease in throughput and battery consumption can be suppressed.

≪ 6. Third Embodiment >>
Next, the mobile device 100B and the wireless communication system 1B according to the third embodiment of the present invention will be described with reference to FIGS. In the present embodiment, in addition to the entrance / exit information 171, the ticket information 172 is stored in the second storage unit 170 of the mobile device 100 </ b> B. The ticket information 172 stores information on express tickets written through a ticket machine installed at a railway station. The limited express ticket is required to board a train that requires an express fee. The hardware configuration of the mobile device 100B is the same as the hardware configuration of the mobile device 100 as shown in FIG.

≪Function≫
First, the function of the mobile device 100B in the third embodiment of the present invention will be described with reference to FIG. As described above, the ticket information 172 is stored in advance in the second storage unit 170 of the mobile device 100B.

  When the detection unit 103B of the mobile device 100B detects that the non-contact communication unit 101 has received the entrance / exit information from the ticket gate 500, the information on the express ticket is written as the ticket information 172 in the second storage unit 170. Is detected, and the contents are notified to the parameter selection unit 104B.

  The parameter selection unit 104B of the mobile device 100B selects the adjustment parameter stored in the adjustment parameter information 152 of the first storage unit 150 according to whether the entry / exit information and the express ticket information detected by the detection unit 103B are written. Then, the selected adjustment parameter is passed to the connection control unit 103B. FIG. 14 shows the relationship between the contents of the entrance / exit information detected by the detection unit 103B and the adjustment parameter to be selected.

  As shown in FIG. 14, when the entry information is received from the ticket gate 500, the parameter selection unit 104B selects the adjustment parameter (high speed) when the ticket information 172 includes information on the express ticket, Otherwise, an adjustment parameter (medium speed) is selected. Also, the parameter selection unit 104B selects the adjustment parameter (normal) when receiving the exit information from the ticket gate 500.

  The connection control unit 103B of the mobile device 100B always uses the adjustment parameter received from the parameter selection unit 104B to perform ranking for cell reselection and event detection for handover regardless of the procedure of Speed dependent scaling. Do.

  With the above function, the mobile device 100B according to the embodiment of the present invention sets the frequency of cell transition low until it passes through the ticket gate of the railway station. Thus, the frequency of cell transition can be set high. As a result, an appropriate cell transition is performed when boarding the railway, while unnecessary cell transitions are suppressed when the railway boarding is not being performed.

≪ Example of operation ≫
Next, operation examples of the mobile device 100B and the wireless communication system 1B according to the third embodiment of the present invention will be described with reference to FIGS.

  FIG. 12 is a diagram illustrating a processing flow of the mobile device 100B according to the third embodiment of the present invention.

  First, when the detection unit 103B detects that the entrance information has been received from the ticket checker 500 (Yes in step S501), the process proceeds to step S502. Otherwise, step S501 is executed again.

  Next, when the detection unit 103B detects that the ticket information 172 in the second storage unit 170 includes the information on the express ticket (Yes in step S502), the parameter selection unit 104B (High speed) is selected (step S503). Otherwise, the process proceeds to step S306, and an adjustment parameter (medium speed) is selected (step S504).

  When the detection unit 103B detects that the exit information has been received from the ticket checker 500 (Yes in step S505), the parameter selection unit 104B selects an adjustment parameter (normal) (step S506) and ends the process. To do. Otherwise, step S505 is executed again.

  With the above processing, the frequency of cell transition can be controlled according to the presence or absence of an express ticket, while the frequency of cell transition can be suppressed when not on a railway.

  FIG. 13 is a sequence diagram illustrating an operation example of the wireless communication system 1B according to the third embodiment of the present invention. In FIG. 13, description of a connection establishment / disconnection sequence, a sequence for executing a handover, and the like performed between the mobile device 100B and the base station or the core network is omitted.

  First, the connection control unit 103B of the mobile device 100B establishes a connection with the base station 310 through a cell selection procedure defined by 3GPP (step S601). Next, the non-contact communication unit 105 of the mobile device 100B receives the entrance information from the ticket checker 500, and writes the information as the entrance / exit information 171 in the second storage unit 170 (step S602). Here, the detection unit 103B detects that the information on the express ticket is included in the ticket information stored in the second storage unit 170 (step S603). Therefore, the parameter selection unit 104B of the mobile device 100B selects an adjustment parameter (high speed) and passes the adjustment parameter to the connection control unit 103B (step S604).

  Next, the connection control unit 103B of the mobile device 100B evaluates Expression (3) using the received adjustment parameter, and detects “Event 3A” (step S605). Then, the connection control unit 103B transmits a report to the base station 310 (step S606). Receiving the report, the base station 310 determines that the mobile device 100B performs handover to the base station 320, and instructs the mobile device 100B to execute processing related to handover (not shown). In response to an instruction from the base station 310, the connection control unit 103B of the mobile device 100B executes processing related to the handover to the base station 320 and connects to the base station 320 (step S607).

  Next, the non-contact communication unit 105 of the mobile device 100B receives exit information from the ticket gate device 500 (step S608). Then, the parameter selection unit 104B of the mobile device 100B selects the adjustment parameter (normal) and passes the adjustment parameter to the connection control unit 103B (step S609).

  As described above, in the wireless communication system 1B according to the third embodiment of the present invention, the frequency of cell transition is switched using the information on the express ticket stored in the mobile device. This makes it possible to set cell transition parameters according to the moving speed. On the other hand, when a moving means such as a railway is not used, unnecessary cell transition can be suppressed by reducing the frequency of cell transition. As a result, throughput reduction and battery consumption due to inadvertent cell transition can be suppressed.

1, 1A, 1B Wireless communication system 1
100, 100A, 100B Mobile device 101 Wireless reception unit 102 Wireless transmission unit 103, 103A, 103B Connection control unit 104, 104A, 104B Parameter selection unit 105 Non-contact communication unit 106, 106A, 106B Detection unit 107 Switching unit 150 First storage Unit 170 second storage unit 200 core network 300 E-UTRAN
310, 320 Base station 410, 420 Sector 415, 425 Cell 500 Ticket gate

Claims (9)

A mobile communication terminal,
A communication unit that communicates with an external system;
A receiving unit that receives information indicating that the moving speed of the mobile communication terminal changes from the external system;
In response to the reception of the information, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the neighboring cell is, the ranking reference value of the neighboring cell is currently being communicated. A selection unit for selecting a parameter used for selection of a base station to be connected, so that a threshold value compared with a time exceeding the ranking reference value of the cell of
A determining unit that determines one base station to be connected from two or more base stations using the selected parameter;
A mobile communication terminal. The external system is a ticket gate,
The communication unit communicates with the ticket gate using the RFIC of the mobile communication terminal.
The mobile communication terminal according to claim 1. The parameter is selected when the moving speed is high, the first parameter selected when the moving speed is medium, and the second parameter selected when the moving speed is normal. Including the third parameter
The mobile communication terminal according to claim 1. A switching unit that switches whether the selection unit can select the first parameter and the second parameter;
The switching unit enables selection of the first parameter and the second parameter when the receiving unit receives information indicating entrance, and the first parameter and the second parameter when the receiving unit receives information indicating exit. Disable parameter selection,
The mobile communication terminal according to claim 3. The receiving unit receives the information from the first ticket gate for high-speed railway and the second ticket gate for ordinary railway,
When the receiving unit receives information representing entrance from the first ticket gate, the selection unit selects the first parameter,
When the receiving unit receives information indicating entry from the second ticket gate, the selecting unit selects the second parameter.
The mobile communication terminal according to claim 3. When the receiving unit receives information indicating entry from the second ticket gate with the first parameter selected, the selecting unit selects the second parameter,
When the receiving unit receives information indicating exit from the second ticket gate with the second parameter selected, the selecting unit selects the third parameter.
The mobile communication terminal according to claim 5. A storage unit for storing ticket information;
When the receiving unit receives the information, the selecting unit selects the parameter according to the ticket information.
The mobile communication terminal according to any one of claims 1 to 3. When the ticket information includes information on an express ticket, the selection unit selects a first parameter used when the moving speed is high,
When the ticket information does not include information on express tickets, the selection unit selects a second parameter used when the moving speed is medium speed.
The mobile communication terminal according to claim 7. A mobile communication method executed by a mobile communication terminal,
A communication stage to communicate with an external system;
Receiving from the external system information indicating that the moving speed of the mobile communication terminal changes; and
In response to receiving the information, the higher the moving speed of the mobile communication terminal is, the higher the moving speed of the mobile communication terminal is, the ranking reference value of the neighboring cell used for determining the selection of the neighboring cell is the ranking of the cell currently in communication A selection step for selecting a parameter used for selection of a base station to be connected so that a threshold value compared with a time exceeding a reference value is small ;
Using the selected parameter to determine a base station to be connected from two or more base stations;
A mobile communication method.

Images