JP2014027532A - Area quality information measurement apparatus, area quality information measurement method, and area quality information measurement program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an area quality information measurement apparatus, an area quality information measurement method, and an area quality information measurement program which, when executing positioning processing by using U-Plane in order to transmit assist data between a mobile terminal unit and a positioning processing device, can measure area quality information in parallel with the positioning processing.SOLUTION: An area quality information measurement unit 64 measures area quality information when a base station positioning processing request signal is determined to have area quality information measurement instruction information added thereto by a quality information measurement instruction state determination unit 63. As an example, the area quality information measurement unit 64 measures area quality information in parallel with positioning processing in an interval from when longitude and altitude information of an MT50 is calculated by an RNC 22 to when the RNC 22 transmits a reply signal to answer the calculated longitude and altitude information to an SLP 41 or EBSCP 42 during an approximate position information calculation processing step among positioning processing steps by an SUPL position method.

Description

  The present invention relates to an area quality information measuring device, an area quality information measuring method, and an area quality information measuring program, and in particular, in a positioning process for measuring a current position of a mobile terminal, a radio wave reception state in each area in a service area The present invention relates to an area quality information measuring apparatus, an area quality information measuring method, and an area quality information measuring program for measuring area quality information.

  However, in any case, it is necessary to measure the area quality information after planning the investigation schedule, and therefore, the investigation requires manpower and time. Therefore, it has been difficult to collect area quality information for each fine area only by collecting area quality information by conducting a travel survey using a radio wave measuring vehicle or the like as described above.

  Meanwhile, there is a GPS (Global Positioning System) positioning method as one of the positioning methods for measuring the current position of the mobile terminal. As an example, also in the wireless communication network system of Patent Document 1 below, positioning processing is performed by the GPS positioning method. In this GPS positioning method, C-Plane (Control-Plane) has been used when transmitting and receiving data necessary for positioning processing between a mobile terminal and a positioning processing device on the network side. Note that C-Plane is a transmission path for transmitting and receiving control signals necessary for establishing or disconnecting communication processing. On the other hand, as for area quality information, a predetermined quality information can be acquired from the mobile terminal by making a measurement request to the mobile terminal via C-Plane from RNC (Radio Network Controller).

  For this reason, a base station radio network control station that controls a plurality of network radio base stations in a centralized manner when requesting a mobile terminal to perform a positioning process by C-Plane from a positioning processor on the network side In the RNC (Radio Network Controller), the mobile terminal was able to perform quality measurement at the same time as the mobile terminal performed the positioning process in C-Plane.

JP2012-015910A

  However, even with the GPS positioning method, there are several positioning methods. One of the positioning methods is an A-GPS (Assisted-Global Positioning System) positioning method using SUPL (Secure User Plane Location). The A-GPS positioning method (SUPL positioning method) using SUPL is a positioning method that is relatively widely used in mobile terminals such as smartphones that are rapidly spreading.

  In the GPS positioning method described in the background art above, C-Plane is used to transmit and receive data necessary for positioning processing between the mobile terminal and the positioning processing device. On the other hand, the A-GPS positioning method using SUPL uses U-Plane (User-Plane) instead of C-Plane as a bearer for transmitting assist data between the mobile terminal and the positioning processing device. ) To perform positioning processing. U-Plane is a transmission path for transmitting and receiving user data. Therefore, in the A-GPS positioning system using SUPL, since there is no opportunity to perform area quality measurement in the RNC during the positioning process, the quality measurement cannot be performed. In other words, in the case of positioning using C-Plane, since the positioning request signal is received by C-Plane at RNC, it is possible to measure quality information at C-Plane at the same time. However, in the A-GPS positioning system using SUPL, since a positioning request is made with a U-Plane signal, the RNC only recognizes the positioning request as user data. For this reason, in the A-GPS positioning system using SUPL, quality measurement cannot be performed in response to a positioning request signal.

  In addition, since the base station (cell base) positioning process performed before the positioning process by the A-GPS positioning method using SUPL is performed using the C-Plane signal, the area quality information is obtained in the base station positioning process. It is also possible to measure. However, if the area quality measurement is performed during the base station positioning process, the approximate position and the acquisition time of the base station positioning result are extended, and as a result, the time required for positioning and the time for notifying the base station positioning result are extended. In other words, base station positioning is calculated based on the cell position, so it can be calculated immediately.However, since the collection of area quality information requires the terminal to perform positioning instructions and report the quality information, the base station positioning process It takes time. In addition, since the base station positioning process for obtaining the approximate position cannot be distinguished from other base station positioning, processing time required for area quality measurement is required even in a service that requires only the base station positioning result. For example, a service in which only people in a specific area can write on a WEB bulletin board can be considered. In such a service, it is only necessary to know the approximate position, so the base station positioning result is used to determine whether it is in a writable area. Therefore, it is necessary to obtain the base station positioning result immediately. In other words, in a service that requires only the base station positioning result, it takes a processing time for area quality measurement to acquire the base station positioning result, which is not preferable because it impedes the speed of the service.

  Further, if area quality information is measured every time all the base station positioning processes that are not accompanied by the positioning process by the A-GPS positioning system using SUPL are performed, the processing time required for performing the positioning process is always performed. , Exceeding the original processing time. As described above, in the service in which the base station positioning process is completed in the above processing time, allowing the processing time required for measuring the area quality information does not hold as a positioning service. Therefore, it is impossible to measure quality uniformly every time all the base station positioning processes are performed.

  Therefore, in view of the above-described problems, the present invention performs parallel to the positioning process when performing the positioning process using U-Plane in order to transmit assist data between the mobile terminal and the positioning processing apparatus. It is an object of the present invention to provide an area quality information measuring apparatus, an area quality information measuring method, and an area quality information measuring program capable of measuring area quality information.

In order to achieve the above object, an area quality information measuring apparatus according to the present invention is configured as follows.
An area quality information measuring device according to an aspect of the present invention provides a transmission path for transmitting and receiving user data in order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation. In the positioning processing process by the A-GPS (Assisted-Global Positioning System) positioning method for performing positioning processing using U-Plane (User-Plane), an outline indicating the approximate position of the mobile terminal from the positioning processing device A base station positioning processing request signal receiving unit that receives a base station positioning processing request signal that is a signal that requests base station positioning processing to calculate location information, and an area where the mobile terminal is located Area quality information, which is information indicating the reception status when receiving radio waves transmitted from the base station A quality information measurement instruction state determination unit that determines whether or not area quality information measurement instruction information, which is information for instructing measurement, is added to the base station positioning processing request signal; and the quality information measurement When it is determined by the instruction state determination unit that the area quality information measurement instruction information is added to the base station positioning processing request signal, the area quality information is measured, and the area quality information measurement instruction information is And an area quality information measuring unit that does not measure the area quality information when it is determined that the base station positioning process request signal is not added.

  According to the above area quality information measuring device, the area quality information measuring unit performs positioning processing using U-Plane in order to transmit assist data between the mobile terminal and the positioning processing device. When performing the base station positioning process associated with the positioning process based on the positioning system, the area quality information is measured in parallel with the positioning process based on the A-GPS positioning system. However, area quality information is not measured when performing base station positioning processing that is not accompanied by positioning processing according to the above positioning method.

Thus, the area quality information is not measured every time all the base station positioning processes are performed. For this reason, when performing base station positioning processing, the processing time required to perform positioning processing does not always exceed the original processing time.
This makes it possible to collect area quality information for each area that is extremely fine so as to cover the entire service area without lowering the service level of positioning processing.
In addition, even in the base station positioning process associated with the positioning process by the A-GPS positioning system, when the positioning by the A-GPS positioning system is not allowed any delay such as the position notification at the time of emergency call, the quality measurement such as user rejection If this is not desired, quality measurements can be excluded.

  In the area quality information measuring device according to an aspect of the present invention, the area quality information measuring unit moves the base station in the calculation process of the approximate position information in the positioning process of the A-GPS positioning method. The area quality information is calculated after the latitude / longitude information indicating the current latitude / longitude of the terminal is calculated until the base station transmits a response signal for responding the latitude / longitude information to the positioning processing device. It is characterized by measuring.

According to the above area quality information measuring device, when the area quality information measuring unit performs the base station positioning process associated with the positioning process by the A-GPS positioning system that performs the positioning process using the U-Plane, the base station Area quality information can be measured in parallel with the positioning process.
In the area quality information measuring device according to an aspect of the present invention, the area quality information measuring unit transmits the area quality information measured by the area quality information measuring unit to the response signal that responds to the latitude and longitude information. It is added together with latitude and longitude information.

According to the above area quality information measuring device, the area quality information measuring unit adds the area quality information together with the latitude and longitude information so that the area quality information is transmitted simultaneously with the latitude and longitude information.
Thereby, the number of response signals is smaller than when the latitude / longitude information and the area quality information are transmitted separately. Therefore, it is possible to prevent an increase in the processing load of each device constituting the wireless communication network system by transmitting and receiving the response signal.

  In the area quality information measuring device according to an aspect of the present invention, the area quality information measuring unit includes the approximate position information transmitted from the positioning processing device in the positioning processing process by the A-GPS positioning method. In the GPS (Global Positioning System) positioning process based on the data, the base station receives the assist data transmitted from the positioning processing device, and then the base station transmits the mobile terminal. The area quality information is measured until a response signal that returns a GPS positioning process result is received.

According to the above area quality information measuring device, when the area quality information measuring unit performs the base station positioning process associated with the positioning process by the A-GPS positioning system that performs the positioning process using the U-Plane, the base station Area quality information can be measured in parallel with the GPS positioning process performed after the positioning process.
In the area quality information measuring device according to an aspect of the present invention, the area quality information measuring unit is configured to output a signal different from the response signal transmitted after the response signal responding to the approximate position information is transmitted. The area quality information measured by the area quality information measuring unit is added.

According to the above area quality information measuring device, the area quality information measuring unit measures the area quality information with respect to a signal different from the response signal transmitted after the response signal responding to the latitude / longitude information is transmitted. The area quality information measured by the section is added.
That is, the latitude / longitude information obtained by performing the positioning process by the base station positioning method and the area quality information measured by the area quality information measuring unit are transmitted in two steps. However, the area quality information measuring unit can measure the area quality information in parallel with the positioning process so as to be within the processing time in the GPS positioning process.

In addition, an area quality information measuring device according to an aspect of the present invention is a device for transmitting and receiving user data in order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation. In a positioning process using an A-GPS (Assisted-Global Positioning System) positioning system that performs a positioning process using a U-Plane (User-Plane) that is a transmission path, an approximate position of the mobile terminal is determined from the positioning processor. A base station positioning process request signal receiving unit that receives a base station positioning process request signal that is a signal requesting to perform a base station positioning process to calculate approximate position information shown;
When positioning by GPS (Global Positioning System) positioning processing performed based on the assist data including the approximate position information transmitted from the positioning processing device in the positioning processing process by the A-GPS positioning method is successful, or The radio wave transmitted from the base station serving the area where the mobile terminal is located only when the error information of the approximate position calculated by the base station positioning process for calculating the approximate position information is sufficiently small An area quality information measurement unit that measures area quality information, which is information indicating a reception state when receiving
It is characterized by providing. In this way, only when the GPS positioning process is successful, by performing the quality measurement process, the load on the entire system can be reduced, and the measured area quality information can be used effectively.

  An area quality information measuring apparatus according to an aspect of the present invention provides a positioning processing service based on the A-GPS positioning system, which is managed in association with subscriber information that uniquely identifies a subscriber who owns the mobile terminal. Based on the contract information acquired by the contract information acquisition unit that acquires contract information indicating the presence or absence of a usage contract and the contract information acquisition unit, it is determined that there is a service usage contract for positioning processing by the A-GPS positioning method. And an area quality information measurement instruction adding unit that adds the area quality information measurement instruction information to the base station positioning processing request signal transmitted to the mobile terminal.

According to the above area quality information measuring device, the area quality information measurement instruction adding unit is based on the A-GPS positioning system that performs positioning processing using U-Plane based on the contract information acquired by the contract information acquiring unit. The area quality information measurement instruction information is added to a base station positioning processing request signal transmitted to a mobile terminal determined to have a positioning processing service use contract. Then, the quality information measurement instruction state determination unit described above determines whether or not the area quality information measurement instruction information is added to the base station positioning process request signal.
Finally, when the area quality information measurement unit performs the base station positioning process associated with the positioning process based on the A-GPS positioning system that performs the positioning process using U-Plane, the area quality information measuring unit performs the positioning process based on the A-GPS positioning system. In parallel, the area quality information described above can be measured.

In the area quality information measuring apparatus according to an aspect of the present invention, the A-GPS positioning method is an A-GPS positioning method using SUPL (Secure User Plane Location).
According to the above area quality information measuring device, positioning by the A-GPS positioning method using SUPL, which is one of the positioning methods that are relatively widely used in mobile terminals such as smartphones that are rapidly spreading. When performing the processing, the area quality information can be measured in parallel with the positioning processing.

  In the area quality information measurement method according to an aspect of the present invention, the base station positioning processing request signal receiving unit transmits assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation. In the positioning processing process by the A-GPS (Assisted-Global Positioning System) positioning system that performs positioning processing using U-Plane (User-Plane), which is a transmission path for transmitting and receiving user data, from the positioning processing device A base station positioning process request signal receiving step for receiving a base station positioning process request signal, which is a signal requesting to perform a base station positioning process to calculate approximate position information indicating the approximate position of the mobile terminal, quality information Whether the measurement instruction state determination unit is a base station serving the area where the mobile terminal is located Area quality information measurement instruction information, which is information for instructing measurement of area quality information, which is information indicating a reception state when a radio wave transmitted from the receiver is received, is added to the base station positioning processing request signal. A quality information measurement instruction state determination step for determining whether or not the area quality information measurement unit determines that the area quality information measurement instruction information is in response to the base station positioning process request signal by the quality information measurement instruction state determination step. The area quality information is measured when it is determined to be added, and the area quality information is measured when it is determined that the area quality information measurement instruction information is not added to the base station positioning processing request signal. It is characterized by having an area quality information measurement step that does not measure.

  According to the above area quality information measurement method, the base station positioning process associated with the positioning process by the A-GPS positioning system that performs the positioning process using the U-Plane is performed by executing each processing step described above. In this case, the area quality information can be measured in parallel with the positioning process by the A-GPS positioning method.

An area quality information measurement program according to an aspect of the present invention provides a computer,
In order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation, U-Plane (User-Plane) that is a transmission path for transmitting and receiving user data is used. In a positioning process based on an A-GPS (Assisted-Global Positioning System) positioning method for performing a positioning process, a base station positioning process is performed to calculate approximate position information indicating an approximate position of the mobile terminal from the positioning processing device. A base station positioning processing request signal receiving unit that receives a base station positioning processing request signal that is a signal requesting that, when receiving a radio wave transmitted from a base station serving an area where the mobile terminal is located Area quality information that is information instructing to measure area quality information that is information indicating a reception state The quality information measurement instruction state determination unit that determines whether or not constant instruction information is added to the base station positioning processing request signal, and the quality information measurement instruction state determination unit determines that the area quality information measurement instruction information is The area quality information is measured when it is determined that it is added to the base station positioning process request signal, and the area quality information measurement instruction information is not added to the base station positioning process request signal Is a program for functioning as an area quality information measurement unit that does not measure the area quality information.

  According to the above area quality information measurement program, it is one of the devices constituting the wireless communication network system, and controls the processing necessary for providing the positioning service, or actually performs the positioning processing. The above-described approximate position information calculation program is executed in a positioning processing device, a base station, or the like that is a platform. Then, in the positioning processing device, the base station, etc., it becomes possible to obtain the same operation as the area quality information measuring device and the area quality information measuring method described above.

  According to the present invention, in order to transmit assist data between a mobile terminal and a positioning processing device, a base station positioning process associated with a positioning process by an A-GPS positioning system that performs a positioning process using U-Plane is performed. When performing, area quality information is measured in parallel with the positioning process by the A-GPS positioning method. However, area quality information is not measured when performing base station positioning processing that is not accompanied by positioning processing according to the above positioning method.

Thus, the area quality information is not measured every time all the base station positioning processes are performed. For this reason, when performing base station positioning processing, the processing time required to perform positioning processing does not always exceed the original processing time.
Thereby, area quality information for each area can be collected so as to cover the entire service area without lowering the service level of the positioning process. In addition, by utilizing the area quality information report created based on the measured area quality information, for example, maintenance of existing equipment such as network radio base stations, work to improve the reception status of each area, and further efficiency Area design can be performed. As a result, it is possible to improve the service quality in providing the service of the wireless communication network system.

1 is a system configuration diagram illustrating a system configuration of a wireless communication network system 10 configured using an area quality information measurement function unit 60 according to the present embodiment. It is a block diagram which shows the function structure of the area quality information measurement function part 60 provided in RNC22. It is a block diagram which shows the function structure of the area quality information measurement function part 80 provided in EBSCP42. The overall flow of the positioning process by the SUPL positioning system including the 1st and 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80 is shown. It is a sequence diagram. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 1st area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 1st area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows the whole flow of the positioning process by the SUPL positioning system including the 2nd area quality information measurement process performed by each apparatus which comprises the radio | wireless communication network system 10 using the area quality information measurement function parts 60 and 80. is there. It is a sequence diagram which shows a part of flow in the case of measuring object terminal determination in the positioning process by the SUPL positioning system including a 1st area quality information measurement process. It is a sequence diagram which shows a part of flow in the case of measuring object terminal determination in the positioning process by the SUPL positioning system including a 2nd area quality information measurement process. It is a sequence diagram which shows a part of flow in the case of measuring object terminal determination in the positioning process by the SUPL positioning system including a 3rd area quality information measurement process.

Hereinafter, preferred embodiments of an area quality information measuring device of the present invention will be described in detail with reference to the accompanying drawings.
(First embodiment)
(System configuration of the wireless communication network system 10)
First, an overall system configuration of the wireless communication network system 10 configured using the area quality information measurement function unit 60 according to the present embodiment will be described with reference to FIG.
FIG. 1 is a system configuration diagram showing a system configuration of a wireless communication network system 10 configured using an area quality information measurement function unit 60 according to the present embodiment. A wireless communication network system 10 illustrated in FIG. 1 includes each device that forms a 3G (3rd Generation) network 20, each device that performs a positioning process mainly using an A-GPS positioning method (SUPL positioning method) using SUPL, A mobile terminal (MT) 50 that is a mobile terminal owned by the user is provided. In this example, a case where the present system is realized in a 3G network will be described. However, the present invention is not limited to this case, and the present system can be realized in another network such as an LTE (Long Term Evolution) network.

In FIG. 1, first, the MT 50 is a mobile terminal such as a smartphone. The MT 50 is a mobile terminal that is a positioning target in the positioning process.
Further, in the wireless communication network system 10, as network devices constituting the 3G network 20, for example, a Node B 21, an RNC 22, an SGSN (serving general packet radio service support node) 23 shown in a broken line frame in FIG. , GGSN (gateway general packet radio service support node) 24 and HSS (Home Subscriber Server) 25 are provided.

The Node B 21 is a network radio base station (BTS; Base Transceiver Station), and the MT 50 is connected by radio (radio waves).
The RNC 22 is actually a base station radio network control station that controls and controls a plurality of network radio base stations.
The SGSN 23 is an exchange constituting a packet network, and is one of the visited level exchanges provided on the MT 50 side. That is, these SGSNs 23 are provided for each area in the service area. And NodeB21 and RNC22 are connected to the MT50 side of SGSN23.

The GGSN 24 is one of the exchanges constituting the packet network. Although not shown, the GGSN 24 is a gateway level exchange provided on the other network side connected to the wireless communication network system 10.
The HSS 25 manages identification information for identifying the MT 50 and subscriber information for specifying the contract contents of the service for each contract (subscriber). The HSS 25 holds the location information when the MT 50 transmits a location registration request signal for requesting location registration. This location information is used to identify a device such as an exchange that is in charge of the area where the MT 50 is located.

Further, the wireless communication network system 10 includes an SLP (SUPL Location Platform) 41, an EBSCP (External Business User Service Control Point) 42, an area quality information collection server device 43, as devices that perform positioning processing by the SUPL positioning method. Is provided.
The SLP 41 performs user authentication and further establishes a secure environment with the MT 50. Then, the SLP 41 generates assist data for the MT 50.

  As described in the background art, the assist data includes approximate position information that is information indicating the approximate position of the MT 50. The approximate position information is “Reference Location” information in a GPS assistance data element defined by 3GPP (Third Generation Partnership Project) of a standardization organization such as 3G system. The approximate position information includes “latitude / longitude information” indicating the coordinates of the current latitude and longitude of the MT 50, “error radius” indicating the accuracy of the distance from the actual position of the MT 50 to the position calculated by positioning, and the like. Location information elements are included.

The EBSCP 42 plays a role of a gateway device when providing position information of the MT 50 to other devices.
The area quality information collection server device 43 stores a radio wave quality (AQ) information such as a radio wave reception state in each area within the service area collected by the SLP 41 and the EBSCP 42 as a database (DB; Database). This database functions as a radio wave quality information database (AQDB) 44. Then, although not shown, the area quality information collection server device 43 is stored in the radio wave quality information database 44 for an analysis server device that analyzes an area quality information report created based on the measured area quality information. Provide area quality information.

  The above-described SLP 41, EBSCP 42, and the like are positioning processing devices that control processing necessary to provide a positioning service using SUPL, or actually perform positioning processing calculations. That is, the SLP 41 and the EBSCP 42 serve as a platform for providing a positioning service using SUPL. In the description of the present embodiment, a positioning method in which a positioning process is performed using U-Plane on a bearer for transmitting assist data between a mobile terminal (MT50) and a positioning processing device (SLP41, EBSCP42, etc.). As an example, a processing example in the case where the above SLP 41 and EBSCP 42 perform a positioning process by the SUPL positioning method will be described.

The above-mentioned SUPL is defined by OMA (Open Mobile Alliance), and a user plane (U-Plane; User-Plane) is used as a communication bearer for transmitting assist data between the MT 50, the SLP 41, the EBSCP 42, and the like. This is the A-GPS positioning method used.
As a method for performing positioning by combining the GPS signal received on the MT50 side and the assist information calculated on the network side, a UE-Based (User Equipment-Based) method and a UE-Assisted (User Equipment-Assisted) There are two methods: In the UE-Base method, the position information is calculated on the MT 50 side using the GPS measurement measured by the own device and the assist signal received from the network side. On the other hand, in the UE-Assisted system, the GPS measurement measured on the MT50 side is transmitted to the SLP41 side of the network, and final position information is calculated on the SLP41 side.

  As an example, the area quality information measuring device of the present invention is provided as the area quality information measuring function unit 60 in the RNC 22 and the area quality information measuring function unit 80 in the EBSCP 42. When the area quality information measurement function units 60 and 80 perform the positioning process by the A-GPS positioning method using SUPL, in parallel with the positioning process, the area quality information measuring function units 60 and 80 This is a functional unit for performing area quality information measurement processing for measuring area quality information. The functional configuration of the area quality information measurement function units 60 and 80 and the specific flow of the entire positioning process using the SUPL positioning method including the area quality information measurement process will be described in detail later.

(Functional configuration of area quality information measurement function unit 60)
Next, the functional configuration of the area quality information measurement function unit 60 provided in the RNC 22 configuring the wireless communication network system 10 according to the present embodiment will be described with reference to FIG.
FIG. 2 is a block diagram showing a functional configuration of the area quality information measurement function unit 60 provided in the RNC 22. The RNC 22 provided with the area quality information measurement function unit 60 shown in FIG. 2 includes a general function unit such as a control signal transmission / reception unit 51 in addition to the area quality information measurement function unit 60. It should be noted that general functional units other than the control signal transmission / reception unit 51 included in the RNC 22 are not shown and description thereof is omitted.

  The control signal transmission / reception unit 51 transmits / receives a control signal necessary for performing the positioning process to / from each device constituting the wireless communication network system 10. For example, the control signal transmission / reception unit 51 performs base station positioning processing to which the area quality information measured by the area quality information measurement unit 64 is added to the SLP 41 via each device constituting the wireless communication network system 10. A response signal is transmitted and the response signal is received.

The area quality information measurement function unit 60 includes a base station positioning processing request signal reception unit 61, a latitude / longitude information calculation unit 62, a quality information measurement instruction state determination unit 63, an area quality information measurement unit 64, and assist data. A receiving unit 65 and a GPS positioning process result receiving unit 66 are provided.
The base station positioning process request signal receiving unit 61 receives a base station positioning process request signal that is a signal for requesting to perform a base station (cell base) positioning process transmitted from the EBSCP 42.

  When the base station positioning processing request signal receiving unit 61 receives the base station positioning processing request signal, the latitude / longitude information calculating unit 62 performs the base station positioning processing to thereby obtain the current latitude and MT of the positioning target MT50. Latitude / longitude information indicating longitude is calculated. Approximate position information indicating the approximate position of the MT 50 can be calculated from position information elements such as latitude and longitude information, and assist data can be calculated from the approximate position information.

  The quality information measurement instruction state determination unit 63 determines whether or not area quality information measurement instruction information is added to the base station positioning process request signal. This area quality information measurement instruction information indicates that the MT 50 measures area quality information, which is information indicating a reception state when a radio wave transmitted from the Node B 21 or the RNC 22 that is in charge of the area in which the MT 50 is located is received. To do. For example, the area quality information measurement instruction information is added by setting the quality measurement flag in the base station positioning processing request signal to the on (valid) state. On the other hand, by setting the state of the quality measurement flag in the base station positioning processing request signal to the off (invalid) state, the area quality information measurement instruction information is not added.

The area quality information measurement unit 64 measures the area quality information when the quality information measurement instruction state determination unit 63 determines that the area quality information measurement instruction information is added to the base station positioning processing request signal. To do. The area quality information measurement unit 64 determines that the area quality information measurement instruction state determination unit 63 determines that the area quality information measurement instruction information is not added to the base station positioning process request signal. Does not measure information. The timing when the area quality information measuring unit 64 measures the area quality information will be described in detail later.
The assist data receiving unit 65 receives assist data transmitted from the SLP 41. As described above, the assist data includes the approximate position information indicating the approximate position of the MT 50.
The GPS positioning process result receiving unit 66 receives the GPS positioning process result (GPS positioning process result) transmitted from the MT 50.

(Functional configuration of area quality information measurement function unit 80)
Next, the functional configuration of the area quality information measurement function unit 80 provided in the EBSCP 42 configuring the wireless communication network system 10 according to the present embodiment will be described with reference to FIG.
FIG. 3 is a block diagram showing a functional configuration of the area quality information measurement function unit 80 provided in the EBSCP 42. The EBSCP 42 provided with the area quality information measurement function unit 80 shown in FIG. 3 includes general function units such as a control signal transmission / reception unit 71 in addition to the area quality information measurement function unit 80. Note that general functional units other than the control signal transmission / reception unit 71 included in the EBSCP 42 are not shown and description thereof is omitted.

  Similar to the control signal transmission / reception unit 51, the control signal transmission / reception unit 71 transmits / receives a control signal necessary for performing the positioning process to / from each device constituting the wireless communication network system 10. For example, the control signal transmission / reception unit 71 is a base station to which area quality information measurement instruction information is added by the area quality information measurement instruction addition unit 82 with the RNC 22 via each device constituting the wireless communication network system 10. A positioning processing request signal is transmitted and a response signal is received.

The area quality information measurement function unit 80 includes a contract information acquisition unit 81 and an area quality information measurement instruction addition unit 82.
The contract information acquisition unit 81 manages contract information indicating whether or not there is a service use contract for various network services or the like in association with subscriber information that uniquely identifies a subscriber who owns the MT 50 from the HSS 25. As one piece of the contract information, contract information indicating whether or not there is a service use contract for positioning processing by the SUPL positioning method is managed.
If the area quality information measurement instruction adding unit 82 determines based on the contract information acquired by the contract information acquiring unit 81 that there is a service use contract for positioning processing by the SUPL positioning method, the area quality information measurement instruction adding unit 82 sets the MT 50 having the service use contract. Area quality information measurement instruction information is added to the transmitted base station positioning processing request signal.

(Overall flow of positioning processing by the SUPL positioning method including the first area quality information measurement processing)
Subsequently, referring to FIG. 4 to FIG. 6, the flow of the first area quality information measurement process performed by each device configuring the wireless communication network system 10 using the area quality information measurement function units 60 and 80, A description will be given according to the overall flow of the positioning process by the SUPL positioning method.
4 to 6 show the entire positioning process by the SUPL positioning method including the first area quality information measuring process performed by each device constituting the wireless communication network system 10 using the area quality information measuring function units 60 and 80. FIG. FIG. The area quality information measurement process described in the first embodiment will be described as a first area quality information measurement process.

  First, in MT50, when the user performs an operation for confirming the current position, a positioning process using the SUPL positioning method is started. Then, as shown in FIG. 4, the MT 50 transmits a positioning start request to the SLP 41 via each device constituting the wireless communication network system 10. By transmitting this positioning start request, the MT 50 requests (requests) the SLP 41 to transmit assist data including approximate position information that is information indicating the approximate position of the MT 50 (step S101).

  Then, the SLP 41 requests the EBSCP 42 to perform an authentication process for a user who owns the MT 50 (step S102). Further, in the EBSCP 42, the contract information acquisition unit 81 obtains identification information for identifying the MT 50 with the HSS 25 and subscriber information necessary for specifying the contract details of the service for each contract (subscriber). Obtain (step S103).

  Here, in the EBSCP 42, the area quality information measurement instruction adding unit 82 is based on the contract information acquired by the contract information acquiring unit 81, and the user possessing the MT 50 has a service use contract for positioning processing by the SUPL positioning method. It is determined whether or not. Then, the area quality information measurement instruction adding unit 82 sets the quality measurement flag in the base station positioning processing request signal to either the on (valid) or off (invalid) state based on the presence or absence of the service use contract. (Step S104). Here, the quality measurement flag is set to an on (valid) state when performing base station positioning processing resulting from SUPL approximate position derivation. On the other hand, when importance is placed on positioning time, such as when positioning is performed based on an emergency call, the quality measurement flag is set to an off (invalid) state.

  For example, the area quality information measurement instruction adding unit 82 provides area quality information measurement instruction information for a base station positioning processing request signal transmitted to the MT 50 possessed by a user who has a service use contract for positioning processing by the SUPL positioning method. Append. When the area quality information measurement instruction information is added, as described above, the area quality information measurement instruction addition unit 82 sets the quality measurement flag in the base station positioning processing request signal to the on (valid) state. good. On the other hand, when the area quality information measurement instruction adding unit 82 does not add the area quality information measurement instruction information to the base station positioning process request signal transmitted to the MT 50 possessed by the user who does not have the service use contract, As described above, the area quality information measurement instruction adding unit 82 may turn off (invalid) the quality measurement flag in the base station positioning processing request signal.

  In the EBSCP 42, the control signal transmission / reception unit 71 transmits a base station positioning processing request signal to which the quality measurement flag is added to the RNC 22 via the devices GGSN 24 and SGSN 23 (steps S105 to S107). In the RNC 22, the base station positioning process request signal receiving unit 61 receives the base station positioning process request signal. Then, the latitude / longitude information calculation unit 62 performs base station positioning processing, so that the latitude / longitude information calculation unit 62 performs latitude / longitude information indicating the latitude / longitude of the current position of the MT 50 that is the positioning target, that is, an approximate position and an error indicating the error. Information is calculated (step S108).

Here, as shown in FIG. 5, each of the devices from RNC 22 to MT 50 performs the area quality information measurement process of steps S201 to S203 shown in a broken line in FIG. This area quality information measurement process is performed only when the quality measurement flag is in the on (valid) state, and is not performed when it is in the off (invalid) state.
First, the RNC 22 determines whether the quality measurement flag added to the base station positioning processing request signal transmitted from the EBSCP 42 is in an on (valid) state or an off (invalid) state (step S201). When the quality information measurement instruction state determination unit 63 determines that the quality measurement flag in the base station positioning processing request signal is on (valid) (YES in step S201), the control signal transmission / reception unit 51 switches the NodeB 21. A control signal for measuring the area quality information is transmitted to the MT 50 via (step S202). Then, in the RNC 22, the control signal transmission / reception unit 51 receives a control signal including area quality information transmitted from the MT 50 via the NodeB 21 (step S203).

  Subsequently, in the RNC 22, the area quality information measuring unit 64 sends the measured area quality information together with the latitude / longitude information to the response signal for responding the latitude / longitude information to the control signal transmitting / receiving unit 51. Instruct. Then, in the RNC 22, the control signal transmission / reception unit 51 transmits a response signal to which the latitude / longitude information, the area quality information, and the error information are added to the EBSCP 42 via the SGSN 23 and the GGSN 24 (step S204). To S206). Thus, by transmitting the latitude / longitude information and the area quality information at the same time, the number of response signals can be reduced as compared to transmitting the latitude / longitude information and the area quality information separately. Therefore, it is possible to prevent an increase in processing load on each device constituting the wireless communication network system by transmitting and receiving response signals.

  If the quality information measurement instruction state determination unit 63 determines that the quality measurement flag in the base station positioning processing request signal is off (invalid) in the RNC 22 (NO in step S201), the control signal transmission / reception unit 51 The control signal for measuring the area quality information is not transmitted to the MT 50 via the NodeB 21. For this reason, in the RNC 22, the control signal transmission / reception unit 51 adds the latitude / longitude information, area quality information such as empty data, and error information to the EBSCP 42 via the SGSN 23 and the GGSN 24. A signal is transmitted (steps S204 to S206). Since the area quality information added to the response signal is empty data or the like, latitude / longitude information and error information are substantially added to the response signal.

  Then, the EBSCP 42 further adds an authentication processing result to the response signal to which the area quality information, the latitude / longitude information, and the error information are added. This authentication processing result is the processing result of the authentication processing performed in response to the authentication processing request in step 102 shown in FIG. Then, the EBSCP 42 transmits a response signal to which latitude / longitude information, area quality information, error information, and an authentication processing result are added (step S207).

  Subsequently, as illustrated in FIG. 6, the SLP 41 transmits assist data to the MT 50 via each device constituting the wireless communication network system 10 as a response to the positioning start request in step S101 of FIG. 5. (Step S301). When the SLP 41 transmits this assist data, the SLP 41 transmits assist data including approximate position information, error information, and satellite information calculated based on the latitude / longitude information received from the RNC 22 to the MT 50. be able to.

  Then, MT50 performs a GPS positioning process based on assist data (step S302). And MT50 transmits a positioning result with respect to SLP41 (step S303). By transmitting this positioning result, the MT 50 transmits the GPS positioning processing result indicating the success or failure of the GPS positioning processing, the latitude / longitude information of the MT 50 obtained by the GPS positioning method, and error information.

  As a final process, the SLP 41 registers the area quality information measured by the area quality information measuring unit 64 in the radio wave quality information database 44 of the area quality information collection server device 43 with respect to the area quality information collection server device 43. (Step S304). When the SLP 41 transmits a request for registering the area quality information to the area quality information collection server device 43, the SLP 41 associates the area quality information with the latitude / longitude information obtained by the GPS positioning method. Send a request to register. Thereby, the area quality information collection server apparatus 43 can manage the quality information in the service area for each area.

(Summary of explanation of area quality information measurement processing in the first embodiment)
As described above, the area quality information measurement unit 64 determines that the quality information measurement instruction state determination unit 63 determines that the area quality information measurement instruction information is added to the base station positioning processing request signal. In addition, area quality information is measured. On the other hand, when the quality information measurement instruction state determination unit 63 determines that the area quality information measurement instruction information is not added to the base station positioning processing request signal, the area quality information measurement unit 64 determines the area quality Does not measure information.

  That is, the base station associated with the positioning process by the A-GPS positioning method in which the area quality information measuring unit performs the positioning process using U-Plane in order to transmit the assist data between the mobile terminal and the positioning processing device. When performing the positioning process, the area quality information is measured in parallel with the positioning process by the A-GPS positioning method. However, the area quality information is not measured when performing the base station positioning process accompanying the positioning process by the above positioning method.

Further, the area quality information measurement unit 64 calculates the latitude / longitude information of the MT50 in the approximate position information calculation process in the positioning process process by the SUPL positioning method, and then the RNC 22 The area quality information is measured until a response signal for responding to the latitude / longitude information is transmitted.
As described above, the area quality information measurement unit 64 does not measure the area quality information every time all the base station positioning processes are performed. And the area quality information measurement part 64 can measure area quality information in parallel with the base station positioning process, when performing the base station positioning process accompanying the positioning process by a SUPL positioning system.

  Note that the time required to calculate the approximate position information is increased by the area quality information measurement process. However, in the case of providing emergency information to the police, fire department, emergency, etc., the area quality information measurement instruction adding unit 82 provides base station positioning processing when providing the caller's location information to the command center receiving the report. The area quality information measurement instruction information may not be added to the request signal. In this way, the positioning processing time can be prioritized rather than measuring the area quality information as necessary.

(Second Embodiment)
The function units constituting the area quality information measurement function units 60 and 80 are substantially the same, but the area quality information measurement unit 64 in the area quality information measurement function unit 60 described with reference to FIGS. The timing at which information is measured can also be changed.

(Overall flow of positioning processing by the SUPL positioning method including the second area quality information measurement processing)
7 to 9, the flow of the second area quality information measurement process performed by each device constituting the wireless communication network system 10 using the area quality information measurement function units 60 and 80 is represented by SUPL. A description will be given according to the overall flow of the positioning processing by the positioning method. The area quality information measurement process described in the second embodiment will be described as a second area quality information measurement process.

7 to 9 show the entire positioning process by the SUPL positioning method including the second area quality information measuring process performed by each device constituting the wireless communication network system 10 using the area quality information measuring function units 60 and 80. FIG. FIG.
First, in each device constituting the wireless communication network system 10, the processes in steps S101 to S108 shown in FIG. However, thereafter, the process of measuring the area quality information in steps S201 to S203 shown in FIG. 5 is not performed. Therefore, as shown in FIG. 7, in the RNC 22, the control signal transmission / reception unit 51 is the first stage in which latitude / longitude information and error information are added to the EBSCP 42 via the SGSN 23 and GGSN 24 devices. The positioning response signal is transmitted (steps S401 to S403).

  Further, the EBSCP 42 adds the result of the authentication process performed in response to the authentication process request in step 102 shown in FIG. 4 to the first-position positioning response signal to which the latitude / longitude information and the error information are added. Then, the EBSCP 42 transmits a first-position positioning response signal to which the authentication processing result, latitude / longitude information, and error information are added, to the SLP 41 (step S404).

Subsequently, as shown in FIG. 8, the SLP 41 assists the MT 50 via each device constituting the wireless communication network system 10 as a response to the assist data transmission request in step S101 shown in FIG. Data is transmitted (step S301). This assist data includes satellite information and latitude / longitude information.
Here, each device from the RNC 22 to the MT 50 performs the area quality information measurement processing in steps S501 to S507 shown in a broken line in FIG.

  First, the RNC 22 determines whether the quality measurement flag added to the base station positioning processing request signal transmitted from the EBSCP 42 is on (valid) or off (invalid) (step S501). When the quality information measurement instruction state determination unit 63 determines that the quality measurement flag in the base station positioning process request signal is on (valid) (YES in step S501), the control signal transmission / reception unit 51 switches the NodeB 21. A quality measurement request signal for measuring area quality information is transmitted to the MT 50 via (step S502). Then, in the RNC 22, the control signal transmission / reception unit 51 receives the quality measurement response signal including the area quality information transmitted from the MT 50 via the NodeB 21 (step S503).

  Subsequently, in the RNC 22, the area quality information measurement unit 64 instructs the control signal transmission / reception unit 51 to add the measured area quality information to the response signal that responds with the latitude / longitude information. Then, in the RNC 22, the control signal transmission / reception unit 51 transmits a second-position positioning response signal to which the area quality information is added to the EBSCP 42 via the SGSN 23 and the GGSN 24 (steps S 504 to S 504). S506).

If the quality information measurement instruction state determination unit 63 determines that the quality measurement flag in the base station positioning processing request signal is off (invalid) in the RNC 22 (NO in step S501), the control signal transmission / reception unit 51 The quality measurement request signal for measuring the area quality information is not transmitted to the MT 50 via the NodeB 21. For this reason, in the RNC 22, the control signal transmission / reception unit 51 sends a second-position positioning response signal to which the area quality information such as empty data has been added to the EBSCP 42 via the SGSN 23 and GGSN 24 devices. Transmit (steps S504 to S506).
Then, the EBSCP 42 transmits a second-stage position positioning response signal to which only area quality information is added to the SLP 41 (step S507).

Subsequently, as shown in FIG. 9, the MT 50 performs GPS positioning processing based on the assist data (step S302). Then, the MT 50 transmits a positioning result and error information to the SLP 41 (step S303). By transmitting this positioning result, the MT 50 transmits the GPS positioning processing result indicating the success or failure of the GPS positioning processing, the latitude / longitude information of the MT 50 obtained by the GPS positioning method, and error information.
As a final process, the SLP 41 registers the area quality information measured by the area quality information measuring unit 64 in the radio wave quality information database 44 of the area quality information collection server device 43 with respect to the area quality information collection server device 43. (Step S304). Thereby, the area quality information collection server apparatus 43 can manage the quality information in the service area for each area.

(Summary of Explanation of Area Quality Information Measurement Processing in Second Embodiment)
Similar to the first embodiment described above, the area quality information measurement unit 64 does not measure the area quality information every time all the base station positioning processes are performed. The area quality information measurement unit 64 can measure the area quality information in parallel with the GPS positioning process performed after the base station positioning process when performing the base station positioning process accompanying the positioning process by the SUPL positioning method. it can.
However, the area quality information measuring unit 64 receives the assist data transmitted from the positioning processing device in the GPS positioning processing step of the positioning processing step by the SUPL positioning method, and then the RNC 22 is transmitted from the MT 50. The area quality information is measured until a response signal that responds to the GPS positioning processing result is received.

  Therefore, the area quality information measuring unit 64 measures the area measured by the area quality information measuring unit with respect to a response signal that is different from the response signal transmitted after the response signal that responds to the latitude / longitude information is transmitted. Add quality information. That is, the latitude / longitude information obtained by performing the positioning process by the base station positioning method and the area quality information measured by the area quality information measuring unit 64 are transmitted from the RNC 22 to the SLP 41 in two steps. To do. Therefore, the number of control signals required for processing increases in the positioning processing process by the SUPL positioning method.

  However, in the GPS positioning process performed based on the assist data transmitted from the SLP 41 in the positioning process based on the SUPL positioning method, after the RNC 22 receives the assist data transmitted from the SLP 41, the RNC 22 transmits from the MT 50. The area quality information can be measured in parallel with the positioning process so as to be within the processing time until the response signal for responding the GPS positioning process result is received.

(Third embodiment)
By the way, when the GPS positioning is successful, the area quality information may be measured. In addition, since indoor areas are often designed with a sufficiently small area, the error information (for example, error radius) of the approximate position calculated by the base station positioning process to calculate the approximate position information is sufficiently small. In this case, area quality information may be measured. Thus, the measured area quality information can be effectively utilized by measuring the area quality information only when the GPS positioning is successful or the error information of the approximate position is sufficiently small. The case where the error information is sufficiently small can be determined by comparing with a predetermined threshold value, for example. In these cases, it is not necessary to use the quality measurement flag used in the first embodiment and the second embodiment.

(Overall flow of positioning processing by the SUPL positioning method including the third area quality information measurement processing)
Referring to FIGS. 10 to 14, the third area quality information measurement process performed by each device constituting the wireless communication network system 10 using the area quality information measurement function units 60 and 80 is represented by the SUPL positioning method. A description will be given in accordance with the overall flow of the positioning process by. The area quality information measurement process described in the third embodiment will be described as a third area quality information measurement process.

  First, in MT50, when the user performs an operation for confirming the current position, a positioning process using the SUPL positioning method is started. Then, as illustrated in FIG. 10, the MT 50 transmits a positioning start request to the SLP 41 via each device configuring the wireless communication network system 10. By transmitting this positioning start request, the MT 50 requests (requests) the SLP 41 to transmit assist data including approximate position information that is information indicating the approximate position of the MT 50 (step S1001).

  Then, the SLP 41 requests the EBSCP 42 to perform an authentication process for a user who possesses the MT 50 (step S1002). Further, in the EBSCP 42, the contract information acquisition unit 81 obtains identification information for identifying the MT 50 with the HSS 25 and subscriber information necessary for specifying the contract details of the service for each contract (subscriber). Obtain (step S1003).

  Here, in the EBSCP 42, the area quality information measurement instruction adding unit 82 is based on the contract information acquired by the contract information acquiring unit 81, and the user possessing the MT 50 has a service use contract for positioning processing by the SUPL positioning method. It is determined whether or not. Then, if there is a service use contract, the area quality information measurement instruction adding unit 82 transmits a base station positioning process request signal.

  In this case, in the EBSCP 42, the control signal transmission / reception unit 71 transmits a base station positioning process request signal to the RNC 22 via each device of the GGSN 24 and the SGSN 23 (steps S1004 to S1006). In the RNC 22, the base station positioning process request signal receiving unit 61 receives the base station positioning process request signal. Then, the latitude / longitude information calculation unit 62 performs base station positioning processing, whereby the latitude / longitude information calculation unit 62 calculates latitude / longitude information indicating the current latitude / longitude of the MT 50 that is the positioning target (step S1007). Further, the calculated latitude / longitude information, that is, error information about the approximate position is calculated (step S1007).

Then, in the RNC 22, the control signal transmission / reception unit 51 transmits a response signal to which the latitude / longitude information and the error information are added to the EBSCP 42 via the SGSN 23 and the GGSN 24 (steps S1008 to S1010).
Then, the EBSCP 42 further adds an authentication processing result to the response signal to which the latitude / longitude information and the error information are added. This authentication processing result is the processing result of the authentication processing performed in response to the authentication processing request in step 1002 shown in FIG. Then, the EBSCP 42 transmits a response signal to which the latitude / longitude information, the error information, and the authentication processing result are added (step S1011).

  Subsequently, as shown in FIG. 11, the SLP 41 transmits assist data to the MT 50 via each device constituting the wireless communication network system 10 as a response to the positioning start request in step S1001 of FIG. (Step S1012). When the SLP 41 transmits this assist data, the SLP 41 transmits assist data including approximate position information, error information, and satellite information calculated based on the latitude / longitude information received from the RNC 22 to the MT 50. be able to.

  Then, MT50 performs a GPS positioning process based on assist data (step S1013). And MT50 transmits a positioning result with respect to SLP41 (step S1014). By transmitting this positioning result, the MT 50 transmits the GPS positioning processing result indicating the success or failure of the GPS positioning processing, and the latitude / longitude information and error information of the MT 50 obtained by the GPS positioning method.

Here, the SLP 41 determines whether the GPS positioning process is successful and whether the error information is sufficiently small based on the received GPS positioning process result (step S1015). If the SLP 41 determines that the GPS positioning process is not successful in the MT 50, or if the error information is not sufficiently small (NO in step S1015), the SLP 41 ends the process and does not perform the subsequent processes.
On the other hand, if the SLP 41 determines that the GPS positioning process is successful in the MT 50, or if the error information is sufficiently small (YES in step S1015), the SLP 41 continues the subsequent processes.

  When continuing the subsequent processing, the SLP 41 transmits a quality measurement request signal to the EBSCP 42 (step S1016). Then, in the EBSCP 42, the area quality information measurement instruction adding unit 82 determines whether the user who owns the MT 50 has a service use contract for the positioning processing by the SUPL positioning method based on the contract information acquired by the contract information acquiring unit 81. Determine whether or not. Then, if there is a service use contract, the area quality information measurement instruction adding unit 82 transmits a quality measurement request signal.

  In this case, in the EBSCP 42, the control signal transmission / reception unit 71 transmits a quality measurement request signal to the RNC 22 via the devices GGSN 24 and SGSN 23 (steps S1017 to S1019). Then, in the RNC 22, the area quality information measuring unit 64 receives the quality measurement request signal. Then, as shown in FIG. 13, each device from RNC 22 to MT 50 performs the area quality information measurement processing in steps S1021 to S1022 shown in broken lines in FIG. That is, the area quality information measurement unit 64 transmits a quality measurement request signal to the MT 50 (step S1021) and receives a quality measurement response signal from the MT 50 (step S1022).

Then, in the RNC 22, the control signal transmission / reception unit 51 transmits a quality information response signal to which the quality information is added to the EBSCP 42 via the SGSN 23 and the GGSN 24 (steps S1023 to S1025).
Then, the EBSCP 42 further adds an authentication processing result to the quality information response signal to which the quality information is added. This authentication processing result is the processing result of the authentication processing performed in response to the authentication processing request in step 1016 shown in FIG. Then, the EBSCP 42 transmits a response signal to which the quality information and the authentication processing result are added (step S1027).

  As a final process, the SLP 41 registers the area quality information measured by the area quality information measuring unit 64 in the radio wave quality information database 44 of the area quality information collection server device 43 with respect to the area quality information collection server device 43. (Step S1028). Thereby, the area quality information collection server apparatus 43 can manage the quality information in the service area for each area.

(Summary of explanation of area quality information measurement processing in the third embodiment)
As described above, the load on the entire system can be reduced by performing the quality measurement process only when the GPS positioning process is successful. Specifically, since the quality information is meaningful only when the GPS positioning is successful, the load on the entire system can be reduced by preventing unnecessary quality measurement.
That is, according to the present embodiment, the area quality information measuring unit measures the area quality information only when the positioning by the GPS positioning process is successful, so that the measured area quality information can be effectively used.

(Measurement terminal determination)
By the way, in each of the above-described embodiments, the quality information measurement process is performed if the quality measurement flag is in the on (valid) state. However, even if the quality measurement flag is set, there may be a problem when the terminal does not have a function for measuring quality, or depending on the terminal, when the quality information measurement process and the GPS positioning process are competing. is there. In consideration of such a case, it may be determined whether or not the terminal is a measurement target terminal before performing the quality measurement process.

  For example, referring to FIG. 14 corresponding to FIG. 5 referred to in the description of the first embodiment, the quality measurement flag added to the base station positioning processing request signal transmitted from the EBSCP 42 is on (valid) in the RNC 22. If the quality measurement flag is in the on (valid) state (YES in step S201), it is further determined whether it is a measurement target terminal (step S201a). . If it is a measurement target terminal, the control signal transmission / reception unit 51 transmits a control signal for measuring area quality information to the MT 50 via the NodeB 21 (step S202). Then, in the RNC 22, the control signal transmission / reception unit 51 receives a control signal including area quality information transmitted from the MT 50 via the NodeB 21 (step S203). If the RNC 22 determines that the terminal is not a measurement target terminal (NO in step S201a), the control signal transmission / reception unit 51 does not transmit a quality measurement request signal for measuring area quality information. Since step S204 and subsequent steps are the same as the processing described with reference to FIG. 5, the description thereof is omitted here.

  Further, referring to FIG. 15 corresponding to FIG. 8 referred to in the description of the second embodiment, in the RNC 22, the quality measurement flag added to the base station positioning processing request signal transmitted from the EBSCP 42 is in an on (valid) state. If the quality measurement flag is in the on (valid) state (YES in step S501), it is further determined whether the terminal is a measurement target terminal (step S501a). . If it is a measurement target terminal, the control signal transmission / reception unit 51 transmits a control signal for measuring area quality information to the MT 50 via the NodeB 21 (step S502). Then, in the RNC 22, the control signal transmission / reception unit 51 receives a control signal including area quality information transmitted from the MT 50 via the NodeB 21 (step S503). If the RNC 22 determines that the terminal is not a measurement target terminal (NO in step S501a), the control signal transmission / reception unit 51 does not transmit a quality measurement request signal for measuring area quality information. Since step S504 and subsequent steps are the same as the processing described with reference to FIG. 8, the description thereof is omitted here.

Further, referring to FIG. 16 corresponding to FIG. 13 referred to in the description of the third embodiment, the RNC 22 determines whether it is a measurement target terminal (step S1024a). If it is a measurement target terminal, the control signal transmission / reception unit 51 transmits a control signal for measuring area quality information to the MT 50 via the NodeB 21 (step S1025). Then, in the RNC 22, the control signal transmission / reception unit 51 receives the control signal including the area quality information transmitted from the MT 50 via the NodeB 21 (step S1026). If the RNC 22 determines that the terminal is not a measurement target terminal (NO in step S1024a), the control signal transmission / reception unit 51 does not transmit a quality measurement request signal for measuring area quality information. Since step S1027 and subsequent steps are the same as the processing described with reference to FIG. 13, the description thereof is omitted here.
As described above, only when the terminal is a measurement target terminal, a quality measurement request is transmitted to a terminal that does not have a function for measuring quality or a terminal that may cause inconvenience by performing quality measurement processing. Network resources can be used effectively.

(Scope of the present invention)
It should be noted that the scope of the present invention is not limited to the illustrated and described exemplary embodiments, but includes all embodiments that provide the same effects as those intended by the present invention. Further, the scope of the invention is not limited to the combinations of features of the invention defined by the claims, but can be defined by any desired combination of specific features among all the disclosed features.

  As an example, in the area quality information measuring apparatus described in the present embodiment, the wireless communication network system 10 is the 3G network 20, but the present invention is not limited to this. The wireless communication network system 10 may be a wireless communication network system in which, for example, a 3G network 20 and an LTE (Long Term Evolution) network exist. Even if the devices constituting the wireless communication network system are changed, the flow of each process of the area quality information measuring device described above is substantially the same.

  Further, in the area quality information measuring device described in the present embodiment, the RNC 22 is provided with an area quality information measuring function unit 60 that is a functional unit as the area quality information measuring device. Further, the area quality information measurement function unit 80 is provided in the EBSCP 42. However, the present invention is not limited to this, and the area quality information measurement function units 60 and 80 may be provided in apparatuses constituting the wireless communication network system 10 other than the RNC 22 and the EBSCP 42. In addition, the function units included in the area quality information measurement function units 60 and 80 may be provided in a single device constituting the wireless communication network system 10. Thus, the functional configuration and device configuration when using the area quality information measurement function units 60 and 80 in the wireless communication network system 10 can be arbitrarily changed according to the form of the wireless communication network.

Further, the area quality information measuring unit 64 measures the area quality information at an arbitrary timing in the process of the base station positioning process and the GPS positioning process, in addition to measuring the area quality information at the timing described in the above embodiments. can do.
In addition, although the above demonstrated the case where A-GPS positioning system was used, A-GPS is only an example, A-GNSS (Assisted-Global Navigation System) such as A-GLONASS (Assisted-Global Navigation Satellite System). ) The present invention can also be applied to positioning.

  The area quality information measuring device according to the present invention is, for example, an area quality information measuring function unit that performs area quality information measurement processing in parallel with the positioning processing when performing positioning processing by the A-GPS positioning method using SUPL. Can be used.

10 …… Wireless communication network system 20 …… 3G network 21 …… NodeB
22 …… RNC
23 …… SGSN
24 …… GGSN
25 …… HSS
41 …… SLP
42 …… EBSCP
43 …… Area quality information collection server device 44 …… Radio wave quality information database (AQDB)
50 …… MT
51 …… Control signal transmission / reception unit 60, 80 …… Area quality information measurement function unit 61 …… Base station positioning processing request signal reception unit 62 …… Latitude / longitude information calculation unit 63 …… Quality information measurement instruction state determination unit 64 …… Area quality information measurement unit 65 …… Assist data reception unit 66 …… GPS positioning processing result reception unit 71 …… Control signal transmission / reception unit 81 …… Contract information acquisition unit 82 …… Area quality information measurement instruction addition unit

In addition, an area quality information measuring device according to an aspect of the present invention is a device for transmitting and receiving user data in order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation. In a positioning process using an A-GPS (Assisted-Global Positioning System) positioning system that performs a positioning process using a U-Plane (User-Plane) that is a transmission path, an approximate position of the mobile terminal is determined from the positioning processor. A base station positioning process request signal receiving unit that receives a base station positioning process request signal that is a signal requesting to perform a base station positioning process to calculate approximate position information shown;
A latitude / longitude information calculating unit that performs the base station positioning process when the base station positioning process request signal receiving unit receives the base station positioning process request signal;
Based on the assist data including the approximate position information calculated by the latitude / longitude information calculation unit transmitted in the base station positioning process, transmitted from the positioning processing device in the positioning processing process of the A-GPS positioning method , If the positioning by the GPS mobile terminal is performed (Global positioning system) positioning processing is determined in the positioning apparatus to be successful, or small enough error information of the approximate position calculated by the base station positioning process Only when it is determined by the positioning processing device, area quality information, which is information indicating a reception state when a radio wave transmitted from a base station serving the area where the mobile terminal is located, is measured. An area quality information measurement unit,
It is characterized by providing. In this way, only when the GPS positioning process is successful, by performing the quality measurement process, the load on the entire system can be reduced, and the measured area quality information can be used effectively.

Claims (10)

In order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation, U-Plane (User-Plane) that is a transmission path for transmitting and receiving user data is used. In a positioning process based on an A-GPS (Assisted-Global Positioning System) positioning method for performing a positioning process, a base station positioning process is performed to calculate approximate position information indicating an approximate position of the mobile terminal from the positioning processing device. A base station positioning processing request signal receiving unit that receives a base station positioning processing request signal that is a signal requesting that,
Area quality information measurement instruction which is information for instructing to measure area quality information which is information indicating a reception state when a radio wave transmitted from a base station serving the area where the mobile terminal is located is received A quality information measurement instruction state determination unit that determines whether information is added to the base station positioning processing request signal;
When the quality information measurement instruction state determination unit determines that the area quality information measurement instruction information is added to the base station positioning processing request signal, the area quality information is measured, and the area quality information An area quality information measurement unit that does not measure the area quality information when it is determined that measurement instruction information is not added to the base station positioning processing request signal;
An area quality information measuring device comprising: The area quality information measurement unit
In the calculation process of the approximate position information in the positioning process by the A-GPS positioning method,
After the base station calculates latitude / longitude information indicating the current latitude / longitude of the mobile terminal, the base station transmits a response signal that responds to the latitude / longitude information to the positioning processing device. The area quality information measuring apparatus according to claim 1, wherein the area quality information is measured. The area quality information measurement unit
The area quality according to claim 2, wherein the area quality information measured by the area quality information measuring unit is added to the response signal that responds to the latitude / longitude information together with the latitude / longitude information. Information measuring device. The area quality information measurement unit
In the GPS (Global Positioning System) positioning processing step performed based on the assist data including the approximate position information transmitted from the positioning processing device in the positioning processing step by the A-GPS positioning method,
Between the time when the base station receives the assist data transmitted from the positioning processing device and the time when the base station receives a response signal that responds to the GPS positioning processing result transmitted from the mobile terminal. The area quality information measuring apparatus according to claim 1, wherein the area quality information is measured. The area quality information measurement unit
The area quality information measured by the area quality information measuring unit is added to a signal different from the response signal transmitted after the response signal that responds to the approximate position information is transmitted. The area quality information measuring device according to claim 4. Contract information acquisition for acquiring contract information indicating presence / absence of service use contract of positioning processing by the A-GPS positioning system, which is managed in association with subscriber information for uniquely specifying a subscriber possessing the mobile terminal And
Based on the contract information acquired by the contract information acquisition unit, the base station positioning processing request signal transmitted to the mobile terminal determined to have a service use contract for positioning processing by the A-GPS positioning method In contrast, an area quality information measurement instruction adding unit for adding the area quality information measurement instruction information,
The area quality information measuring device according to claim 1, further comprising: In order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation, U-Plane (User-Plane) that is a transmission path for transmitting and receiving user data is used. In a positioning process based on an A-GPS (Assisted-Global Positioning System) positioning method for performing a positioning process, a base station positioning process is performed to calculate approximate position information indicating an approximate position of the mobile terminal from the positioning processing device. A base station positioning processing request signal receiving unit that receives a base station positioning processing request signal that is a signal requesting that,
When positioning by GPS (Global Positioning System) positioning processing performed based on the assist data including the approximate position information transmitted from the positioning processing device in the positioning processing process by the A-GPS positioning method is successful, or The radio wave transmitted from the base station serving the area where the mobile terminal is located only when the error information of the approximate position calculated by the base station positioning process for calculating the approximate position information is sufficiently small An area quality information measurement unit that measures area quality information, which is information indicating a reception state when receiving
An area quality information measuring device comprising: The A-GPS positioning method is
The area quality information measuring apparatus according to any one of claims 1 to 7, wherein the area quality information measuring apparatus is an A-GPS positioning system using SUPL (Secure User Plane Location). The base station positioning processing request signal receiving unit is a transmission path for transmitting and receiving user data in order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation. -In a positioning process using an A-GPS (Assisted-Global Positioning System) positioning system that performs positioning processing using Plane (User-Plane), approximate position information indicating the approximate position of the mobile terminal is obtained from the positioning processing device. A base station positioning process request signal receiving step for receiving a base station positioning process request signal which is a signal for requesting to perform a base station positioning process to calculate,
The quality information measurement instruction state determination unit instructs to measure area quality information, which is information indicating a reception state when a radio wave transmitted from a base station serving the area where the mobile terminal is located is received. Quality information measurement instruction state determination step for determining whether or not area quality information measurement instruction information that is information to be added to the base station positioning processing request signal,
When the area quality information measurement unit determines in the quality information measurement instruction state determination step that the area quality information measurement instruction information is added to the base station positioning processing request signal, the area quality information measurement unit An area quality information measuring step that measures and does not measure the area quality information when it is determined that the area quality information measurement instruction information is not added to the base station positioning processing request signal Area quality information measurement method. Computer
In order to transmit assist data between a mobile terminal that is a positioning target and a positioning processing device that performs positioning processing calculation, U-Plane (User-Plane) that is a transmission path for transmitting and receiving user data is used. In a positioning process based on an A-GPS (Assisted-Global Positioning System) positioning method for performing a positioning process, a base station positioning process is performed to calculate approximate position information indicating an approximate position of the mobile terminal from the positioning processing device. A base station positioning process request signal receiving unit for receiving a base station positioning process request signal that is a signal requesting that
Area quality information measurement instruction which is information for instructing to measure area quality information which is information indicating a reception state when a radio wave transmitted from a base station serving the area where the mobile terminal is located is received A quality information measurement instruction state determination unit for determining whether information is added to the base station positioning processing request signal;
When the quality information measurement instruction state determination unit determines that the area quality information measurement instruction information is added to the base station positioning processing request signal, the area quality information is measured, and the area quality information An area quality information measurement program for functioning as an area quality information measurement unit that does not measure the area quality information when it is determined that measurement instruction information is not added to the base station positioning processing request signal.

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