JP5107807B2 - Test apparatus and method for mobile phone terminal - Google Patents

Description

  The present invention is used for mobile phone terminal protocol development and function test, for example, chip set, mobile phone terminal coding / decoding processing function test, protocol sequence test (location registration / outgoing / incoming / mobile / network side disconnection).・ Testing equipment for mobile phone terminals that can test various applications such as handover, etc., voice communication, data communication (circuit switching, packet), mobile device facing, etc. and middleware (software located between OS and applications) And a method.

  Conventionally, when testing a protocol developed for a mobile phone terminal, for example, a test apparatus 51 as shown in FIG. 8 has been used. In the test apparatus 51 of FIG. 8, the base station simulator control unit 52 controls the base station simulator 53 and executes a test scenario describing the mobile phone terminal protocol, so that the mobile phone terminal to be tested instead of the real network Data is communicated with W and the protocol is tested.

  By the way, in this type of test apparatus 51, a protocol test is performed by transmitting and receiving control (C plane) data to and from the mobile phone terminal W based on a test scenario. There was no particular application testing by sending and receiving data. However, when developing a mobile phone terminal, an application is developed separately from the protocol development described above, and it is necessary to test this application. In the end, it was desired to conduct a test combining a protocol and an application.

  Therefore, the base station simulator 53 of the test apparatus 51 of FIG. 8 is provided with a port 53a for connecting the application server 54 via, for example, Ethernet (registered trademark) so that an application test can be performed. Thus, the user connects the application server 54 to the base station simulator 53, performs data communication between the application server 54 and the mobile phone terminal W via the base station simulator 53, and tests the application.

  However, in the test apparatus 51 of FIG. 8, the application server 54 is left to the user side. For this reason, it has not been possible to easily perform a competition test or a reproduction of a defect phenomenon in communication between the application layer and the mobile phone terminal protocol layer.

  Moreover, the test scenario of the mobile phone terminal protocol and the test scenario of the mobile phone terminal application are described in different test platforms. For this reason, when a failure occurs, there is a problem that it is difficult to distinguish whether the cause is on the base station simulator 53 side or the application server 54 side.

  By the way, when a network-assisted GPS receiver corresponding to the above-described mobile phone terminal W is inspected, it is necessary to connect to a server via a network. In order to solve the problem, an invention of an inspection apparatus that includes a signaling tester that is a pseudo base station and a simulated satellite signal generator that is a pseudo GPS server and inspects a GPS receiver is disclosed in Patent Document 1 below. Has been.

  More specifically, the inspection apparatus 61 disclosed in Patent Document 1 generates a simulated satellite signal having a simulated carrier generator 62a, a PN code generator 62b, a spread modulator 62c, an attenuator 62d, etc., as shown in FIG. A simulated satellite signal simulating an actual satellite signal is generated from the device 62, and the simulated satellite signal is radiated from the transmission antenna 63. Then, a simulated positioning instruction is given to the inspection target product W from the personal computer 64 constituting the simulated server or the signaling tester 65 linked thereto. This simulated positioning instruction includes satellite number information in the same manner as the positioning instruction. The inspection target product W receives and captures the simulated satellite signal in accordance with the simulated positioning instruction. Further, the personal computer 64 collects information on the operation contents or results of the inspection target product W.

Patent Document 2 below discloses a DTM communication apparatus that performs simultaneous communication of voice communication and packet data communication in the GSM system with a smooth connection procedure. The DTM communication device disclosed in Patent Document 2 determines whether or not a voice call is in progress with the configuration shown in FIG. 10, and was in voice communication when a packet data communication request was made. In this case, radio resource allocation processing is performed for this.
JP 2003-255039 A JP 2007-208722 A

  However, in the inspection device 61 disclosed in Patent Document 1, since the personal computer 64 and the signaling tester 65 cannot perform the cooperative operation of the mobile phone protocol and the GPS server command, the mobile phone protocol and the application (GPS) competition test and malfunction There was a problem that the phenomenon could not be reproduced.

  In addition, the DTM communication device disclosed in Patent Document 2 has a problem that it is not possible to perform a competition test or a failure phenomenon reproduction in communication between the mobile phone terminal protocol layer and the application layer. In any case, in the conventional configuration including the technology disclosed in Patent Document 1 and Patent Document 2 described above, it is not possible to perform a competition test or a failure phenomenon reproduction in communication between the mobile phone terminal protocol layer and the application layer. It was.

  Therefore, the present invention has been made in view of the above problems, and a mobile phone terminal test apparatus capable of easily performing a competition test and a failure phenomenon reproduction in communication between a mobile phone terminal protocol layer and an application layer, and It aims to provide a method.

In order to achieve the above object, a test apparatus for a mobile phone terminal according to claim 1 of the present invention sets the mobile phone terminal as a test target W, and the mobile phone terminal according to the mobile phone terminal protocol described in scenario 4a. A base station simulator 2 that performs data communication between them, an application server unit 3 that operates autonomously as an application server that operates on the mobile phone terminal, and a base station simulator control unit 4 that controls the base station simulator and the application server unit A mobile phone terminal testing apparatus 1 comprising:
The base station simulator 2 receives uplink data from the mobile phone terminal, identifies the received uplink data into a mobile phone terminal protocol message and application user data, and the identified mobile phone terminal protocol. A function of transmitting a message to the base station simulator control unit and transmitting the identified user data for application to the application server unit, downlink application data from the application server unit, and downlink from the base station simulator control unit A function of multiplexing data and transmitting the data to the mobile phone terminal;
The application server unit 3 includes an uncontrolled application server unit 3c that operates autonomously as a server of application data that is not controlled by the scenario that operates on the mobile phone terminal, and is controlled by the scenario from the application user data. A function for identifying application data to be, a function for transmitting application data to be controlled of the identified scenario to the base station simulator control unit, downlink application data from the non-controllable application server unit, and the base A function to multiplex the downlink application data from the station simulator control unit and transmit to the base station simulator,
The base station simulator control unit 4 determines whether or not the mobile phone terminal protocol message from the base station simulator and the application data from the application server unit are desired based on the scenario. The determination result has a function of transmitting data according to the scenario as the downlink data to the base station simulator and the application server unit.

The test apparatus for a mobile phone terminal according to claim 2 uses the mobile phone terminal application software used in the mobile phone terminal as a test object W, and artificially tests the mobile phone according to the mobile phone terminal protocol described in scenario 4a. A base station simulator simulating unit 5 that performs data communication with a terminal, an application server unit 3 that operates autonomously as a server of an application that operates on the mobile phone terminal, and a base station that controls the base station simulator simulating unit and the application server unit A mobile phone terminal testing apparatus 1 including a simulator control unit 4,
The application server unit 3 includes a non-controllable application server unit 3c that operates autonomously as a server of application data that is not controlled by the scenario that operates on the mobile phone terminal, and follows the mobile phone terminal protocol described in the scenario A function of identifying application data to be controlled by the scenario from uplink application data by the mobile phone terminal application software in a state in which data communication with the mobile phone terminal is being performed in a pseudo manner; and A function of transmitting control target application data to the base station simulator control unit; downlink application data from the non-control target application server unit; and downlink application data from the base station simulator control unit And a function of transmitting by multiplexing and Yondeta,
The base station simulator control unit determines whether the application data from the application server unit is desired based on the scenario, and determines the data according to the scenario based on the determination result as the downlink application data. It has the function to transmit to the said application server part.

The test method for a mobile phone terminal according to claim 3 is a base station simulator 2 for performing data communication with the mobile phone terminal according to the mobile phone terminal protocol described in scenario 4a, with the mobile phone terminal as a test object W. And the application server unit 3 that autonomously operates as a server for applications that operate on the mobile phone terminal, and the base station simulator control unit 4 that controls the base station simulator and the application server unit, and tests the mobile phone terminal A test method for a mobile phone terminal,
Receiving upstream data from the mobile phone terminal, and identifying the received upstream data into a mobile phone terminal protocol message and application user data;
Transmitting the identified mobile phone terminal protocol message to the base station simulator control unit and transmitting the identified application user data to the application server unit;
Identifying application data to be controlled in the scenario from the application user data;
Transmitting the application data to be controlled of the identified scenario to the base station simulator control unit;
Transmitting the identified non-controlled application data of the scenario to the non-controlled application server unit 3c operating autonomously as a server of non-controlled application data of the scenario operating on the mobile phone terminal;
Determining whether the application data is desired based on the scenario, and transmitting data according to the scenario to the application server unit as the downlink application data according to the determination result;
A step of multiplexing and transmitting downlink application data from the non-controllable application server unit and downlink application data from the base station simulator control unit;
And a step of multiplexing the downlink application data from the application server unit and the downlink data from the base station simulator control unit and transmitting the multiplexed data to the mobile phone terminal.

According to a test method for a mobile phone terminal described in claim 4, the mobile phone terminal application software used in the mobile phone terminal is set as a test object W, and the mobile phone is simulated in accordance with a mobile phone terminal protocol described in scenario 4a. A base station simulator simulating unit 5 that performs data communication with a terminal, an application server unit 3 that operates autonomously as a server of an application that operates on the mobile phone terminal, and a base station that controls the base station simulator simulating unit and the application server unit A test method for a mobile phone terminal comprising the simulator control unit 4 and testing the mobile phone terminal application software,
Identifying application data to be controlled by the scenario from uplink application data by the mobile phone terminal application software in a state where data communication with the mobile phone terminal is performed in a pseudo manner according to the mobile phone terminal protocol described in the scenario And steps to
Transmitting the application data to be controlled of the identified scenario to the base station simulator control unit;
Transmitting the identified non-controlled application data of the scenario to the non-controlled application server unit 3c operating autonomously as a server of non-controlled application data of the scenario operating on the mobile phone terminal;
It is determined based on the scenario whether the application data from the application server unit is desired, and data according to the scenario is transmitted to the application server unit as the downlink application data based on the determination result. Steps,
And a step of multiplexing and transmitting downlink application data from the non-control target application server unit and downlink application data from the base station simulator control unit.

  According to the present invention, it is possible to describe a test scenario for a mobile phone terminal protocol and a test scenario for a mobile phone terminal application on the same test platform. As a result, it is possible to easily reproduce the competition test and the trouble phenomenon in the communication between the application layer and the mobile phone terminal protocol layer, which has been difficult to realize until now.

  In addition, a scenario that assumes the use of a base station simulator (a scenario that stores both a mobile phone terminal protocol test scenario and a mobile phone terminal application test scenario) may be used for testing mobile phone terminal application software alone. it can.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings. FIG. 1 is a block diagram of a first embodiment of a test apparatus for a mobile phone terminal (hereinafter abbreviated as a test apparatus) according to the present invention, FIG. 2 is a block diagram showing a general-purpose configuration of FIG. 1, and FIG. FIG. 4 is a diagram showing a specific hierarchical structure of the base station simulator and application server unit in FIG. 1, FIG. 4 is a block configuration diagram of a second embodiment of the test apparatus according to the present invention, and FIG. 5 is a general configuration of FIG. FIG. 6 is a diagram showing a specific hierarchical structure of the base station simulator and the application server unit in FIG. 4, and FIG. 7 is a block diagram of a third embodiment of the test apparatus according to the present invention.

  The test apparatus according to the present invention is used for protocol development and function test of a mobile phone terminal, and includes a chip set, a function test of coding / decoding processing of a mobile phone terminal, a protocol sequence test (location registration / outgoing / incoming / mobile / Network side disconnection, handover, etc.), application tests such as voice call, data communication (circuit switching, packet), mobile station facing, etc.

  In the test apparatus according to the present invention, the configuration of the first to third embodiments described below easily realizes a competition test and a reproduction of a malfunction phenomenon in communication between the mobile phone terminal protocol layer and the application layer.

  First, a first embodiment of a test apparatus according to the present invention will be described with reference to FIGS.

  As shown in FIG. 1, a test apparatus 1 (1A) according to the first embodiment has a mobile phone terminal as a test target W, and includes a base station simulator 2, an application server unit 3, and a base station simulator control unit 4, and is schematically configured. Is done.

  The base station simulator 2 is a signaling tester that performs data communication in accordance with a mobile phone terminal protocol message and application data described in scenario 4a to be described later, and as shown in FIG. 1, an upstream data receiving unit 2a, a data identifying unit 2b, and a downlink data transmission unit 2c.

  The uplink data receiving unit 2a receives uplink data from the mobile phone terminal that is the test object W, and sends the received uplink data to the data identifying unit 2b.

  The data identifying unit 2b identifies the cellular phone terminal uplink data received by the uplink data receiving unit 2a as a cellular phone terminal protocol message and application user data. The identified mobile phone terminal protocol message is transmitted to the base station simulator control unit 4. The identified application user data is transmitted to the application server unit 3.

  The downlink data transmission unit 2c multiplexes the mobile phone terminal protocol message received from the base station simulator control unit 4 and the downlink application data received from the application server unit 3, and the multiplexed data is the mobile phone that is the test target W. Sending to the phone terminal.

  Here, the base station simulator 2 has a hierarchical structure of layer 1 and layer 2 as shown in FIG. 2 in order to enable software tests such as various applications and middleware. Here, as a specific configuration specialized for GSM + SUPL, as shown in FIG. 3, the base station simulator 2 has a hierarchical structure of PHY, RLC / MAC, LLC, and SNDCP. 2a and the downstream data transmission unit 2c are realized. Further, in the hierarchical structure of FIG. 3, the LLC realizes the function of the data identification unit 2b.

  PHY (Physical) is defined in the standard: 3GPP TS 45.001. The PHY functions as a physical layer control block that controls the physical layer (the lowest layer of the OSI reference model) that defines the data representation format and interface shape on the transmission path. In the PHY, packet data communication is performed with a mobile phone terminal that is the test target W by a radio frequency signal, and packet data and a communication control message are output to an upper layer of the hierarchical structure.

  RLC / MAC (Radio Link Control / Media Access Control) is defined in the standard: 3GPP TS 44.060. RLC / MAC is a radio link / medium that performs link control related to radio, such as data division, combining, and retransmission control for reliably and efficiently delivering data to the other party, and conversion of each communication channel for delivering data to the other party. It functions as an access control block.

  And between PHY and RLC / MAC, transmission / reception of user (U plane) data and control (C plane) data of the GSM / GPRS system is performed.

  The LLC (Logical Link Control) functions as a logical link control block for performing link control for establishing a packet communication path when packet data is transmitted and received, and is defined in the standard: 3GPP TS44.064. Further, in the LLC, the C-plane (mobile phone terminal protocol message) and U-plane (application user data) of the GSM / GPRS system are identified by analyzing the head part of the LLC layer. The LLC transmits the identified U plane to the SNDCP, and transmits the identified C plane to the base station simulator control unit 4.

  SNDCP (Subnetwork Dependent Convergence Protocol) functions as a network integrated protocol control block that controls matching of protocols related to packet data communication between the base station simulator 2 and the network, and is defined in the standard: 3GPP TS 44.065. The In SNDCP, the U plane from LLC is transmitted to the application server unit 3. In SNDCP, the U plane from the application server unit 3 is transmitted to the LLC.

  The application server unit 3 operates as a server of an application client that operates on a cellular phone terminal protocol described in scenario 4a described later, and is configured by a terminal device such as a personal computer. As shown in FIG. An application data reception unit 3a, a data identification unit 3b, an uncontrolled application server unit 3c, and a downlink application data transmission unit 3d are provided.

  The uplink application data receiving unit 3a receives application user data (U-plane) from the base station simulator 2, and sends the received application user data to the data identifying unit 3b.

  The data identifying unit 3b identifies whether the application user data (U-plane) received by the uplink application data receiving unit 3a is application data to be controlled in a scenario 4a described later. The application user data identified as the scenario control target is transmitted to the base station simulator control unit 4. In addition, the application user data identified as being out of the scenario control target is transmitted to the non-control target application server unit 3c.

  The non-control-target application server unit 3c operates autonomously as a server that operates on the mobile phone terminal that is the test target W based on the application user data that is not subject to scenario control from the data identification unit 3b.

  The downlink application data transmission unit 3d multiplexes the downlink application data received from the base station simulator control unit 4 with the application data received from the non-control-target application server unit 3c, and transmits the multiplexed application data to the base station simulator 2. is doing.

  Here, the application server unit 3 has a hierarchical structure of a network / transport layer and a presentation layer as shown in FIG. 2 in order to enable testing of software such as various applications and middleware. Here, as a specific configuration specialized for GSM + SUPL, as shown in FIG. 3, the application server unit 3 has a hierarchical structure of TCP / IP and TLS, and the upstream application data receiving unit 3a and the downstream are structured by these hierarchical structures. The function of the application data transmission unit 3d is realized. TCP / IP realizes the function of the data identification unit 3b.

  TCP / IP (Transmission Control Protocol / Internet Protocol) is defined by standards: IETF RFC791 and RFC793. In TCP / IP, a packet data connection is established, and whether or not the application data is controlled by a scenario 4a to be described later is identified from the TCP port number of the application user data.

  TLS (Transport Layer Security) is defined in the standard: IETF RFC2246. In TLS, a connection established by TCP / IP is encrypted. In TLS, user authentication can also be performed.

  As shown in FIG. 1, the base station simulator control unit 4 includes a scenario 4a and a scenario control unit 4b. The base station simulator control unit 4 performs base station communication to perform data communication according to the mobile phone terminal protocol message and application data described in the scenario 4a. The station simulator 2 and the application server unit 3 are controlled.

  In scenario 4a, the test scenario of the mobile phone terminal protocol and the test scenario of the mobile phone terminal application are described on the same test platform. More specifically, this scenario 4a includes various conditions (protocol messages and applications to be controlled) for the base station simulator 2 to perform data communication with the mobile phone terminal in accordance with the procedure specified by the 3GPP GSM / GPRS standard. Data).

  The scenario 4a includes L3 (Layer 3). For example, the relationship between the base station simulator 2 and the mobile phone terminal, such as the message setting relationship and the relationship between the frequency and signal output to the mobile phone terminal that is the test target W. Various communication procedures exchanged between them are defined.

  The scenario control unit 4b analyzes the scenario 4a and controls the base station simulator 2 and the application server unit 3 according to the procedure of the analysis result. The scenario control unit 4b determines whether the mobile phone terminal protocol message received from the base station simulator 2 and the application user data received from the application server unit 3 are desired based on the scenario 4a. Transmission data corresponding to the result is transmitted to the base station simulator 2 and the application server unit 3. That is, the downlink mobile phone terminal protocol message is transmitted to the base station simulator 2 as the transmission data corresponding to the determination result, and the downlink application data is transmitted to the application server unit 3.

  In addition, the scenario control unit 4b includes the layer 3 control unit 4ba and the application control unit 4bb as shown in FIG. 2 in order to have the above-described transmission / reception function and enable software tests such as various applications and middleware. Yes. Here, as a specific configuration specialized for GSM + SUPL, the scenario control unit 4b includes a GSM / GPRS control unit 4ba and a SUPL control unit 4bb as shown in FIG.

  GSM (Global Systems for Mobile communications) is a second generation mobile phone (2G) standard realized by the FDD-TDMA system, and is defined by standards: 3GPP TS44.018 and TS24.008.

  As shown in FIG. 3, a simulated positioning instruction (including satellite number information) is given to a mobile phone terminal that is a test object W from an external GPS simulator 7 that simulates a GPS satellite. The mobile phone terminal that is the test object W receives and captures the simulated satellite signal according to the satellite number information included in the simulated positioning instruction.

  GPRS (General Packet Radio Service) is defined by standards: 3GPP TS44.018, TS24.008, and SUPL (Secure User Plane Location) is defined by standard: Secure User Plane Location Architecture Approved Version 1.0-15 Jun 2007. Is done.

  The GSM / GPRS control unit 4ba performs transmission / reception control of the C plane of the GSM / GPRS system, and receives the uplink mobile phone terminal protocol message identified by the base station simulator 2. In addition, the GSM / GPRS control unit 4ba transmits the downlink mobile phone terminal protocol message described in the scenario 4a to the base station simulator 2.

  The SUPL control unit 4bb performs transmission / reception control of SUPL data, and receives the uplink application data identified by the application server unit 3. Further, the SUPL control unit 4bb transmits the downlink application data described in the scenario 4a to the application server unit 3.

  It is determined whether the mobile phone terminal protocol message received from the base station simulator 2 or the application user data received from the application server unit 3 is desired, and the transmission data corresponding to the determination result is transmitted to the base station. The scenario 4a can be directly provided with a function to be transmitted to the simulator 2 or the application server unit 3.

  In the test apparatus 1A of the first embodiment having the above-described configuration, when the scenario 4a of the base station simulator 2 is started, the base station simulator 2 receives the uplink data from the mobile phone terminal that is the test target W.

  The base station simulator 2 identifies the received uplink data as a mobile phone terminal protocol message and application user data. Then, the identified mobile phone terminal protocol message is transmitted to the base station simulator control unit 4. Also, the identified application user data is transmitted to the application server unit 3.

  The application server unit 3 identifies whether the application user data is scenario-controlled application data. Then, the application user data identified as the scenario control target is transmitted to the base station simulator control unit 4. Further, the application user data identified as being out of the scenario control target is transmitted to the non-control target application server unit 3c.

  The non-control-target application server unit 3c operates autonomously as a server that operates on the mobile phone terminal that is the test target W based on the application user data identified as being out of the scenario control target.

  In addition, the base station simulator control unit 4 transmits to the application server unit 3 application data corresponding to the scenario-targeted application user data from the application server unit 3. Then, the application server unit 3 multiplexes the application data from the non-control target application server unit 3c and the application data from the base station simulator control unit 4, and transmits the multiplexed application data to the mobile phone terminal. By repeating the above operation, various tests of the mobile phone terminal based on the scenario 4a are performed.

  Next, as an example of a specific operation of the test apparatus 1 configured as described above, a GSM / GPRS, SUPL operation confirmation test of a mobile phone terminal using the test apparatus 1 will be described.

  First, the scenario of the base station simulator 2 is started. Subsequently, the mobile phone terminal (3GPP GSM / GPRS and OMA SUPL standard compliant) that is the test target W is turned on. Thereafter, the mobile phone terminal performs location registration in the base station simulator 2 according to a GSM / GPRS location registration (registration) procedure defined by the 3GPP GSM / GPRS standard. At this time, there is no data exchange between the mobile phone terminal as the test target W and the application server unit 3. At that time, the scenario control unit 4b of the base station simulator control unit 4 can confirm whether or not the mobile phone terminal conforms to the 3GPP GSM / GPRS standard.

  Subsequently, the operator operates the user interface of the mobile phone terminal so as to acquire the position information on the mobile phone terminal side that is the test target W. Accordingly, the mobile phone terminal establishes a data session with the application server unit 3 via the base station simulator 2 in accordance with the PDP CONTEXT establishment procedure defined in the 3GPP GSM / GPRS standard. At that time, the scenario control unit 4b (scenario 4a) can confirm whether or not the mobile phone terminal complies with the 3GPP GSM / GPRS standard.

  Subsequently, the mobile phone terminal acquires GPS assist data from the base station simulator 2 under the control of the base station simulator control unit 4 according to the OMA SUPL standard. At that time, the scenario control unit 4b (scenario 4a) can check whether the mobile phone terminal conforms to the OMA SUPL standard.

  Furthermore, in the mobile phone terminal, after acquiring the position information, as an example, the operator may connect the mobile phone terminal to a Web server that is not controlled by scenario 4a, and acquire Web information linked with the position information. it can. At that time, it can be confirmed on the mobile phone terminal side whether correct Web information has been acquired.

  Note that the mobile phone terminal that is the test target W can be connected to a GPS simulator described in the scenario 4a, for example, to acquire position information.

  As described above, in the test apparatus 1A according to the first embodiment having the above configuration, the base station simulator control unit 4 controls the base station simulator 2 and the application server unit 3 according to the scenario 4a described in the same test platform, and performs the test. By performing data communication with the mobile phone terminal that is the target W, it is possible to perform the test of the protocol and the application that are controlled in the scenario 4a on the same test platform. Further, even in a state where an application that is not controlled in scenario 4a is in operation, it is possible to test the protocol and application that are controlled by the scenario in parallel.

  Next, a second embodiment of the test apparatus according to the present invention will be described with reference to FIGS. In addition, in the test apparatus 1 (1B) of the second embodiment shown in FIGS. 4 to 6, the same components as those of the test apparatus 1A of the first embodiment described above are denoted by the same reference numerals, and the description thereof is omitted. ing.

  As shown in FIGS. 4 to 6, the test apparatus 1 </ b> B according to the second embodiment uses the mobile phone terminal application software that can be used in the mobile phone terminal as a test target W, and The base station simulator 2 in the test apparatus 1A is changed to the base station simulator simulation unit 5, and the other configurations are the same as the test apparatus 1A of the first embodiment.

  In the test apparatus 1B of the second embodiment, the mobile phone terminal application software that is the test target W is installed in advance in the terminal apparatus 8 such as a personal computer.

  The base station simulator simulation unit 5 includes a terminal device such as a personal computer, and includes an uplink data reception simulation unit 5a and a downlink data transmission simulation unit 5b. According to the mobile phone terminal protocol message described in the scenario 4a. It performs data communication with a mobile phone terminal in a pseudo manner.

  As shown in FIG. 6, in the terminal device 8, a simulated positioning instruction (including satellite number information) is given from the GPS signal simulation unit 8a that simulates a GPS satellite to the mobile phone terminal application software that is the test target W. It is supposed to be. The mobile phone terminal that is the test object W receives and captures the simulated satellite signal according to the satellite number information included in the simulated positioning instruction.

  In the test apparatus 1B of the second embodiment, the application server is in a state in which data communication with the mobile phone terminal is performed in a pseudo manner by the uplink data reception simulation unit 5a and the downlink data transmission simulation unit 5b of the base station simulator simulation unit 5. The uplink application data receiving unit 3a of the unit 3 receives the uplink application data from the mobile phone terminal application software that is the test target W. Then, the data identification unit 3b identifies whether or not the uplink application data is the scenario control target application data.

  Then, the uplink application data identified as the scenario control target is transmitted to the base station simulator control unit 4. In addition, the application data identified as being out of the scenario control target is transmitted to the non-control target application server unit 3c.

  The non-control-target application server unit 3c operates autonomously as a server that operates on the mobile phone terminal that is the test target W based on the application data that is not subject to scenario control from the data identification unit 3b.

  In addition, the base station simulator control unit 4 transmits to the application server unit 3 application data for the scenario control target application data from the application server unit 3. Then, the application server unit 3 multiplexes the application data from the non-controllable application server unit 3c and the application data from the base station simulator control unit 4, and the mobile phone terminal application software installs the multiplexed application data. Is transmitted to the selected terminal device.

  As described above, according to the second embodiment, the base station simulator 2 is replaced with the base station simulator simulation unit 5, and in addition to the same effects as those of the first embodiment described above, it is assumed that the base station simulator is used. Scenario 4a (scenario storing both the mobile phone terminal protocol test scenario and the mobile phone terminal application test scenario) can be used for testing the mobile phone terminal application software alone.

  Next, a third embodiment of the test apparatus according to the present invention will be described with reference to FIG. In the test apparatus 1 (1C) of the third embodiment shown in FIG. 7, the same components as those of the test apparatus 1A of the first embodiment described above are denoted by the same reference numerals, and description thereof is omitted.

  The test apparatus 1C according to the third embodiment has the basic configuration of the test apparatus 1A according to the first embodiment described above, and separates the application server unit 3 from a non-controllable application server unit 3c (terminal device such as a personal computer). The non-controllable application server unit 3c is connected via, for example, Ethernet (registered trademark). Also, another application server unit 3 (3B) is connected between the base station simulator 2 and the application server 3 via the Ethernet (registered trademark) via a relay device 6 such as a hub (HUB) or a router. It is a configuration.

  The relay device 6 in the test device 1C of the third embodiment has a function of identifying whether or not the uplink data from the base station simulator 2 received from the mobile phone terminal that is the test target W is the application data to be controlled in the scenario 4a. have.

  Although not particularly illustrated, in the configuration of FIG. 5, another application server unit is installed between the terminal device in which the mobile phone terminal application software is installed and the application server unit 3 via, for example, Ethernet (registered trademark). It is good also as a structure to connect. Moreover, it is good also as a structure which comprises the non-controllable application server part 3c separately with respect to the application server part 3, and connects the non-controllable application server part 3c via Ethernet (trademark), for example.

  Further, although not shown, the application server unit 3 includes a configuration without the presentation layer in FIGS. 2 and 5 and the TLS in FIGS. 3, 6 and 7.

  According to the present invention, it is possible to describe the test scenario of the mobile phone terminal protocol and the test scenario of the mobile phone terminal application on the same test platform. As a result, it is possible to easily reproduce the competition test and the trouble phenomenon in the communication between the application layer and the mobile phone terminal protocol layer, which has been difficult to realize until now.

  For example, a primitive transmission / reception of 3GPP signaling protocol and an application layer message sequence by OMA SUPL can be described as one scenario, and the user can freely define the message issue timing of both.

  Also, as shown in FIGS. 4 to 6, the base station simulator 2 is replaced with the base station simulator simulation unit 5, and the scenario (the mobile phone terminal protocol test scenario and the mobile phone terminal is assumed to be used). A scenario storing both application test scenarios) can be used for testing the mobile phone terminal application software alone.

  As described above, according to the present invention, since the scenarios of the conventional GPS pseudo signal generator and the signaling tester can be described on the same platform, the timing can be freely defined by the operator. Thereby, a general-purpose test environment for a mobile phone terminal application can be provided.

  In addition, since the mobile phone terminal protocol and the application scenario can be described on the same platform, application control in conjunction with the mobile phone terminal protocol scenario becomes possible.

  In addition, the reproducibility of the test can be sufficiently obtained by the scenario control of the application, and the test can be performed even when the application that is not controlled by the scenario is operating. Furthermore, it is possible to test directly connected to the emulation environment of the mobile phone terminal, and the scenario can also be diverted.

  Further, in the above-described embodiment, as an example of a configuration specialized for GSM + SUPL, a case where various application tests are performed together with a test of a cellular phone protocol has been described as an example, but a similar configuration (the general-purpose configuration illustrated in FIGS. 2 and 5 is used). The middleware (software located between the OS and the application) can also be tested according to the configuration.

It is a block block diagram of 1st Embodiment of the test apparatus which concerns on this invention. It is a block diagram which shows the general purpose structure of FIG. It is a figure which shows the specific hierarchical structure of the base station simulator and application server part in FIG. It is a block block diagram of 2nd Embodiment of the testing apparatus which concerns on this invention. It is a block diagram which shows the general purpose structure of FIG. It is a figure which shows the specific hierarchical structure of the base station simulator and application server part in FIG. It is a block block diagram of 3rd Embodiment of the test apparatus which concerns on this invention. It is a schematic block diagram of the conventional test apparatus. It is a block diagram of the inspection apparatus disclosed by patent document 1. It is a block diagram of the DTM communication apparatus disclosed by patent document 2.

Explanation of symbols

1 (1A, 1B, 1C) Test device 2 Base station simulator 2a Uplink data reception unit 2b Data identification unit 2c Downlink data transmission unit 3 Application server unit 3a Uplink application data reception unit 3b Data identification unit 3c Non-controllable application server unit 3d Downlink application data transmission unit 4 Base station simulator control unit 4a Scenario 4b Scenario control unit 4ba GSM / GPRS control unit 4bb SUPL control unit 5 Base station simulator simulation unit 5a Uplink data reception simulation unit 5b Downlink data transmission simulation unit 6 Relay device 7 GPS Simulator 8 Terminal device 8a GPS signal simulator W Test target (mobile phone terminal, mobile phone terminal application software)

Claims (4)

A base station simulator (2) that performs data communication with the mobile phone terminal in accordance with the mobile phone terminal protocol described in the scenario (4a), with the mobile phone terminal as a test target (W), and operates on the mobile phone terminal A mobile phone terminal testing device (1) comprising an application server unit (3) that operates autonomously as an application server, and a base station simulator control unit (4) that controls the base station simulator and the application server unit. And
The base station simulator (2) receives uplink data from the mobile phone terminal, identifies the received uplink data into a mobile phone terminal protocol message and application user data, and the identified mobile phone A function of transmitting a terminal protocol message to the base station simulator control unit and transmitting the identified application user data to the application server unit, downlink application data from the application server unit, and the base station simulator control unit And the function of multiplexing the downlink data and transmitting to the mobile phone terminal,
The application server unit (3) includes an uncontrolled application server unit (3c) that operates autonomously as a server of application data that is not controlled by the scenario that operates on the mobile phone terminal. A function for identifying application data to be controlled by a scenario, a function for transmitting application data to be controlled for the identified scenario to the base station simulator control unit, and a downlink application from the non-control-target application server unit A function of multiplexing data and downlink application data from the base station simulator control unit and transmitting the data to the base station simulator,
The base station simulator control unit (4) determines whether the mobile phone terminal protocol message from the base station simulator and the application data from the application server unit are desired based on the scenario. A test apparatus for a mobile phone terminal having a function of determining and transmitting data according to the scenario as the downlink data to the base station simulator and the application server unit based on the determination result. A base station simulator simulation unit which performs a data communication with the mobile phone terminal in accordance with the mobile phone terminal protocol described in the scenario (4a) with the mobile phone terminal application software used in the mobile phone terminal as a test target (W) (5), an application server unit (3) that operates autonomously as a server for applications that operate on the mobile phone terminal, a base station simulator control unit (4) that controls the base station simulator simulation unit and the application server unit, A mobile phone terminal testing apparatus (1) comprising:
The application server unit (3) includes a non-controllable application server unit (3c) that operates autonomously as a server of application data that is not controlled by the scenario that operates on the mobile phone terminal, and the mobile phone described in the scenario A function of identifying application data to be controlled in the scenario from uplink application data by the mobile phone terminal application software in a state in which data communication with the mobile phone terminal is performed in a pseudo manner according to a telephone terminal protocol; A function of transmitting application data to be controlled in the scenario to the base station simulator control unit, downlink application data from the non-control target application server unit, and downlink application data from the base station simulator control unit. And a function of transmitting the multiplexed and publication data,
The base station simulator control unit determines whether the application data from the application server unit is desired based on the scenario, and determines the data according to the scenario based on the determination result as the downlink application data. And a function of transmitting to the application server unit. A base station simulator (2) that performs data communication with the mobile phone terminal in accordance with the mobile phone terminal protocol described in the scenario (4a), with the mobile phone terminal as a test target (W), and operates on the mobile phone terminal An application server unit (3) that operates autonomously as an application server, and a base station simulator control unit (4) that controls the base station simulator and the application server unit, and for testing the mobile phone terminal A test method,
Receiving upstream data from the mobile phone terminal, and identifying the received upstream data into a mobile phone terminal protocol message and application user data;
Transmitting the identified mobile phone terminal protocol message to the base station simulator control unit and transmitting the identified application user data to the application server unit;
Identifying application data to be controlled in the scenario from the application user data;
Transmitting the application data to be controlled of the identified scenario to the base station simulator control unit;
The step of transmitting the identified application data outside the control target of the scenario to the non-control target application server unit (3c) operating autonomously as a server of the application data outside the control target of the scenario operating on the mobile phone terminal When,
Determining whether the application data is desired based on the scenario, and transmitting data according to the scenario to the application server unit as the downlink application data according to the determination result;
A step of multiplexing and transmitting downlink application data from the non-controllable application server unit and downlink application data from the base station simulator control unit;
A test method for a mobile phone terminal, comprising: multiplexing downlink application data from the application server unit and downlink data from the base station simulator control unit and transmitting the multiplexed data to the mobile phone terminal. A base station simulator simulation unit which performs a data communication with the mobile phone terminal in accordance with the mobile phone terminal protocol described in the scenario (4a) with the mobile phone terminal application software used in the mobile phone terminal as a test target (W) (5), an application server unit (3) that operates autonomously as a server for applications that operate on the mobile phone terminal, a base station simulator control unit (4) that controls the base station simulator simulation unit and the application server unit, A test method for a mobile phone terminal for testing the mobile phone terminal application software comprising:
Identifying application data to be controlled by the scenario from uplink application data by the mobile phone terminal application software in a state where data communication with the mobile phone terminal is performed in a pseudo manner according to the mobile phone terminal protocol described in the scenario And steps to
Transmitting the application data to be controlled of the identified scenario to the base station simulator control unit;
The step of transmitting the identified application data outside the control target of the scenario to the non-control target application server unit (3c) operating autonomously as a server of the application data outside the control target of the scenario operating on the mobile phone terminal When,
It is determined based on the scenario whether the application data from the application server unit is desired, and data according to the scenario is transmitted to the application server unit as the downlink application data based on the determination result. Steps,
A test method for a mobile phone terminal, comprising: a step of multiplexing and transmitting downlink application data from the non-controllable application server unit and downlink application data from the base station simulator control unit.

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