JP5814413B2 - Test apparatus and test method - Google Patents

Description

  The present invention relates to a test apparatus and a test method for testing an operation of a communication function by communicating with a pseudo terminal that simulates a communication function of a mobile communication terminal that transmits and receives a radio frequency signal corresponding to a predetermined communication standard.

  When a mobile communication terminal such as a mobile phone is newly developed, it is necessary to test whether or not the developed mobile communication terminal operates normally in an environment where it is actually used. However, whether or not the newly developed communication terminal operates normally by transmitting / receiving various types of test communication information between the newly developed communication terminal and the actual base station already in operation. It is very difficult to test.

  For this reason, a pseudo base station having the function of an actual base station is provided, and a newly developed mobile communication terminal is connected to the pseudo base station, and various types of communication information are transmitted and received between the mobile communication terminal and the pseudo base station. Thus, there has been proposed a test apparatus that performs a test of whether or not a newly developed mobile communication terminal operates normally (see, for example, Patent Document 1).

  By the way, since this type of test apparatus is intended for testing a mobile communication terminal that has been implemented in hardware, the mobile communication terminal has to perform an operation check after the mobile communication terminal has been implemented as hardware. Since the development period of the system will be prolonged, improvement is desired.

  Therefore, before making the mobile communication terminal hardware, a general-purpose computer is used to realize a pseudo terminal that simulates the communication function of the mobile communication terminal to be tested, and the pseudo terminal and the pseudo base station are connected by wire. Thus, a configuration for confirming the communication function of the pseudo terminal can be considered. In this case, for example, as described in Patent Document 2, the baseband signal is input and output to test the pseudo terminal, and the baseband signal is transmitted between the pseudo terminal and the pseudo base station via the network. It is convenient and preferable to use a configuration for transmitting and receiving packets including

JP 2014-006618 A JP 2010-527173 A

  However, the test apparatus having the above-described configuration cannot communicate with the mobile communication terminal in real time (real time) as in an actual use environment, and is in non-real time (non-real time) communication.

  Specifically, when a computer simulating a mobile communication terminal to be tested is used, processing time due to computer hardware resource control and software control is generated. Therefore, compared to a mobile communication terminal having a communication-dedicated IC. The signal processing time becomes long, and the mobile communication terminal and the pseudo base station cannot communicate in real time as in the actual usage environment.

  Also, in a configuration in which packets are transmitted and received between a computer and a pseudo base station via a network, packet retransmission, retransmission due to loss, etc. occur. The station cannot communicate in real time.

  By the way, when testing an actual terminal, since communication is possible in real time, it is possible to evaluate whether or not the communication timing is appropriate by verifying a communication log including real-time time information. For example, when a certain message is transmitted from the test apparatus to the terminal and a response message is received from the terminal in response to the message, it may be considered that the tester checks the communication log and confirms the time lag from transmission to reception.

  On the other hand, in the case of a pseudo terminal that cannot perform a communication operation in real time as described above, the calculation time varies depending on the processing content. I can't judge. Thus, when testing a pseudo terminal that cannot perform a communication operation in real time, it is difficult to evaluate whether the communication timing is appropriate.

  The present invention has been made in view of the circumstances as described above, and a test apparatus that allows a tester to evaluate whether or not the timing of communication is appropriate even when testing a pseudo terminal that cannot perform a communication operation in real time. And to provide a test method.

A test apparatus according to claim 1 of the present invention communicates with a pseudo terminal (100) that simulates a communication function of a mobile communication terminal that transmits and receives a radio frequency signal in accordance with a predetermined communication standard, and operates the communication function. A test apparatus (1) for testing, wherein the pseudo terminal is configured to manage a simulation time which is a time in the operation of the communication function, which is different from a real time, and transmits the simulation time to the test apparatus A processing time table in which a data type of data to be processed and an actual time required for the mobile communication terminal to process the data are provided in advance, and when transmitting data to the test apparatus, before the data by referring to the processing time table in processing start time of the data plus the actual time required for the transfer Dodori signal terminal handles Transmitting / receiving means (21) for transmitting / receiving digital data of a baseband signal to / from the pseudo terminal, wherein first time information which is a time in simulation time is transmitted to the test apparatus; The data to be transmitted to the pseudo terminal by performing a reception arithmetic process on the uplink data that is the data received by the transmission / reception means from the pseudo terminal according to the communication standard, and performing a transmission arithmetic process according to the communication standard And a management unit (30) for managing the simulation time. The management unit includes a calculation unit (40) that generates the downlink data and sends the generated downlink data to the transmission / reception unit. Is time information acquisition means (31) for acquiring the first time information received by the transmission / reception means. And when the downlink data is transmitted after obtaining the first time information, the simulation time obtained by adding the calculation time of the reception calculation process and the transmission calculation process to the time of the first time information Second time information that is time is generated, and the generated second time information is transmitted from the transmitting / receiving means to the pseudo terminal, and time information adding means (33) is included.

  With this configuration, when transmitting the downlink data, the test apparatus according to claim 1 of the present invention uses the time in the simulation time based on the first time information and the calculation time of the reception calculation process and the transmission calculation process. Since the second time information is generated and the generated second time information is transmitted from the transmission / reception means to the pseudo terminal, the communication timing is appropriate even when testing the pseudo terminal that cannot perform the communication operation in real time. The tester can evaluate whether.

  In the test apparatus according to claim 2 of the present invention, the calculation means includes a plurality of layers in which each process is defined by the communication standard, and the test apparatus performs communication between predetermined layers of the calculation means. Log data generating means (13) for generating log data, and log display means (16) for displaying a log based on the log data, wherein the log data generating means stores time information at the simulation time. The log data is generated, and the log display means is configured to display the log including time information at the simulation time.

  With this configuration, in the test apparatus according to claim 2 of the present invention, the log data generation unit generates log data including time information at the simulation time, and the log display unit displays a log including time information at the simulation time. Therefore, even when testing a pseudo terminal that cannot perform a communication operation in real time, the tester can evaluate whether or not the communication timing is appropriate.

  In the test apparatus according to a third aspect of the present invention, the log data generation means generates the log data including time information in the real time in addition to time information in the simulation time, and the log display means It has a configuration for displaying the log in which the time information in the simulation time and the time information in the real time are written together.

  With this configuration, the test apparatus according to claim 3 of the present invention can display a log in which time information in simulation time and time information in real time are written together.

  The test apparatus according to claim 4 of the present invention includes a reception buffer (22a) for temporarily storing the uplink data received by the transmission / reception means from the pseudo terminal, and the downlink data sent by the calculation means. A transmission buffer (22b) for temporarily storing the management means, wherein the management means is conditioned on the condition that the time information acquisition means has acquired the first time information. On condition that the calculation start notification means (32) for notifying the calculation means of an instruction for performing the reception calculation processing for link data and the time information addition means have generated the second time information Transmission notification means (34) for notifying the transmission / reception means of an instruction for transmitting the downlink data stored in the transmission buffer; It has a configuration having a.

  With this configuration, the test apparatus according to claim 4 of the present invention can synchronize with the pseudo terminal even when testing a pseudo terminal that cannot perform a communication operation in real time. It is possible to accurately evaluate pseudo terminals that cannot communicate with each other.

  The test apparatus according to claim 5 of the present invention has a configuration in which the communication function of the pseudo terminal is realized by a software program.

  With this configuration, the test apparatus according to claim 5 of the present invention enables the tester to evaluate whether or not the communication timing is appropriate even when the communication function of the pseudo terminal realized by the software program is the test target. it can.

  The test apparatus according to claim 6 of the present invention has a configuration in which the communication function of the pseudo terminal is realized by a semiconductor integrated circuit.

  With this configuration, the test apparatus according to claim 6 of the present invention tests whether the communication timing of the communication function of the semiconductor integrated circuit is appropriate even when the semiconductor integrated circuit that processes the baseband signal is the test target. Can be evaluated.

A test method according to claim 7 of the present invention communicates with a pseudo terminal (100) that simulates a communication function of a mobile communication terminal that transmits and receives a radio frequency signal in accordance with a predetermined communication standard, and operates the communication function. a test method for testing, the pseudo terminal is different from the real time, with adapted to manage a is simulation time period in the operation of the communication function, the data type of data to be transmit this data includes the processing time table real time and is associated in advance required to process said mobile communication terminal, when transmitting the data, the processing start time of the data in the simulation time time in the simulation time plus the actual time required for the data by referring to the processing time table for the transfer Dodori signal terminal handles A first time information is transmitted, the uplink data which is digital data of a baseband signal and the first time information are received from the pseudo terminal (S11), and the communication standard And performing a reception calculation process on the uplink data (S14), and performing a transmission calculation process according to the communication standard to generate downlink data that is digital data of a baseband signal to be transmitted to the pseudo terminal Adding the calculation time of the reception calculation process and the transmission calculation process to the time of the first time information when transmitting the downlink data after acquiring the first time information. Generating second time information that is a time in the simulation time (S22); It has a step (S24) for transmitting down link data and the second time information to the pseudo-terminal, the arrangement comprising a.

  With this configuration, when transmitting downlink data, the test method according to claim 7 of the present invention is based on the first time information and the calculation time of the reception calculation process and the transmission calculation process. Since the second time information is generated and the generated second time information is transmitted from the transmission / reception means to the pseudo terminal, the communication timing is appropriate even when testing the pseudo terminal that cannot perform the communication operation in real time. The tester can evaluate whether.

  The present invention can provide a test apparatus and a test method by which a tester can evaluate whether or not the timing of communication is appropriate.

It is a block block diagram of the base station simulator in one Embodiment of this invention. It is a figure which shows an example of the processing time table in which the data classification and the processing time of the data were linked | related in the base station simulator in one Embodiment of this invention. It is the figure which illustrated notionally the test scenario of the base station simulator in one Embodiment of this invention. It is a figure which shows an example of the log which the display part of the base station simulator in one Embodiment of this invention displays. It is a flowchart of the reception process of the base station simulator in one Embodiment of this invention. It is a flowchart of the transmission process of the base station simulator in one Embodiment of this invention. It is a timing chart of the base station simulator in one Embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. An example in which the test apparatus of the present invention is applied to a base station simulator that tests a pseudo terminal that simulates a communication function of a mobile communication terminal by simulating a base station will be described.

  First, the structure of the base station simulator in this embodiment is demonstrated.

  As shown in FIG. 1, the base station simulator 1 in the present embodiment tests the communication function of the UE simulator 100 by communicating with a UE (User Equipment) simulator 100. The UE simulator 100 simulates a communication function of a mobile phone or a mobile terminal that transmits and receives a radio frequency signal in accordance with a predetermined communication standard, for example, a communication standard called LTE (Long Term Evolution).

  The base station simulator 1 includes an interface 21, a buffer unit 22, a simulation time management unit 30, a base station simulation calculation unit 40, a scenario processing unit 12, a log data generation unit 13, a log data storage unit 14, a display control unit 15, and a display unit. 16 and an operation unit 17 are provided. The base station simulator 1 includes a microcomputer equipped with a CPU, ROM, RAM, FPGA, an input / output circuit to which various interfaces are connected, and the like (not shown). That is, the base station simulator 1 causes the microcomputer to function as a base station simulator for testing the UE simulator 100 by executing a control program stored in advance in the ROM. The base station simulator 1 constitutes a test apparatus according to the present invention.

  The interface 21 converts baseband data (hereinafter simply referred to as “IQ data”) of I-phase components (in-phase components) and Q-phase components (orthogonal components), which are downlink data generated by the base station simulation calculation unit 40, to the UE simulator. 100 and at the same time receive IQ data as uplink data from the UE simulator 100. The interface 21 constitutes transmission / reception means according to the present invention.

  In the present embodiment, as an example, the interface 21 is connected to the UE simulator 100 using a TCP / IP (Transmission Control Protocol / Internet Protocol) as a communication protocol via a best effort type network such as Ethernet (registered trademark). Communicate. Therefore, the interface 21 has functions such as IP packet generation, IP address assignment, source and destination specification, data transmission path selection, error correction, and retransmission request. However, the transmission / reception means according to the present invention is not limited to this, and known transmission / reception means such as a wireless LAN (Local Area Network) or USB (Universal Serial Bus) may be used.

  The buffer unit 22 includes a reception buffer 22a and a transmission buffer 22b. The reception buffer 22a temporarily stores IQ data received from the UE simulator 100 by the interface 21. The transmission buffer 22b temporarily stores IQ data waiting for transmission transmitted from the interface 21 to the UE simulator 100.

  The simulation time management unit 30 includes a time stamp (TS) acquisition unit 31, a calculation start notification unit 32, a time stamp addition unit 33, and a transmission notification unit 34. The simulation time management unit 30 manages a simulation time that is advanced according to the time information of the IQ data acquired by the time stamp acquisition unit 31 and is different from the actual time due to the progress of the real time. ing. In addition, the simulation time management unit 30 is configured to control the base station simulator 1 in an integrated manner.

  The time stamp acquisition unit 31 acquires the time information of the IQ data by monitoring the time information (time stamp) of the IQ data stored in the reception buffer 22a. Here, the time stamp is added at the time of generating IQ data in the UE simulator 100, and is different from the actual time, and is time information (simulation time) at a simulation time which is a time in the operation of the communication function of the UE simulator 100. Time information). Note that the base station simulation calculation unit 40 according to the present embodiment outputs the IQ data for which the calculation has been completed to the time stamp addition unit 33 when the calculation of the input IQ data has been completed. Further, the time stamp acquisition unit 31 constitutes time information acquisition means according to the present invention.

  The calculation start notification unit 32 gives an instruction (first instruction) to the base station simulation calculation unit 40 to perform reception calculation processing on uplink data on the condition that the time stamp acquisition unit 31 has acquired time information. It comes to notify. This calculation start notification unit 32 constitutes calculation start notification means according to the present invention.

  The time stamp adding unit 33 generates time information (second time information) in the simulation time and adds it to the IQ data as a time stamp. The time stamp adding unit 33 constitutes time information adding means according to the present invention.

  The transmission notification unit 34 notifies the interface 21 of an instruction (second instruction) for transmitting downlink data on condition that the time stamp adding unit 33 adds time information at the simulation time to the IQ data. It is supposed to be. The transmission notification unit 34 constitutes a transmission notification unit according to the present invention.

  The actual base station is configured to perform signal processing based on a clock frequency of 10 MHz, for example, but the base station simulator 1 is configured to perform signal processing (slow clock processing) at a clock frequency of 1 kHz for example. Processing can also be performed.

  The base station simulation calculation unit 40 includes a layer processing unit 41 and a message processing unit 42. The base station simulation calculation unit 40 reads uplink data from the UE simulator 100 from the reception buffer 22a according to a predetermined communication standard, performs reception calculation processing, and performs transmission calculation processing according to the communication standard to downlink. Data is generated, and the generated downlink data is stored in the transmission buffer 22b. In addition, the base station simulation calculation part 40 comprises the calculating means which concerns on this invention.

  The layer processing unit 41 includes a PHY 41a that performs processing of a PHY layer (Physical Layer), a MAC 41b that performs processing of an upper MAC layer (Medium Access Control Layer), and an upper RLC layer (Radio) RLC 41c for processing the Link Control Layer (radio link control layer), PDCP 41d for processing the upper PDCP layer (Packet Data Convergence Protocol Layer, packet data convergence layer), and RRC layer (Radio Resource Control Layer, radio above) An RRC 41e that performs processing of the resource control layer) is provided. Each of these layers constitutes a layer according to the present invention.

  The layer processing unit 41 is configured to perform communication protocol processing of each layer corresponding to a predetermined communication standard, processes communication data from the interface 21 and sends it to the message processing unit 42, and The message is processed and sent to the interface 21. At this time, the layer processing unit 41 outputs communication data, which is the content of communication between layers, to the log data generation unit 13 every time processing is performed in each layer.

  The message processing unit 42 generates a message to be transmitted to the UE simulator 100 under the control of the scenario processing unit 12 and sends the message to the layer processing unit 41, and receives the message from the UE simulator 100 via the interface 21 and the layer processing unit 41. It is designed to process messages.

  The scenario processing unit 12 reads out the test scenario from the scenario storage unit 12a that stores the test scenario in advance, and controls each unit of the base station simulation calculation unit 40 including the message processing unit 42.

  FIG. 2 conceptually shows an example of a test scenario. The test scenario describes a communication sequence indicating communication contents and communication order with the UE simulator 100 and settings of each unit of the base station simulator 1. In addition to the initial setting, this setting includes changing the setting of the base station simulator 1 during the execution of the test. In FIG. 2, as an example of settings, initial settings and setting changes during test execution are described for PDCP layer encryption.

  The log data generation unit 13 includes a time generation unit 13a and an ID generation unit 13b, and generates log data from communication data output from the layer processing unit 41. The log data generation unit 13 constitutes log data generation means according to the present invention.

  The time generation unit 13a generates time information that is the actual time or the elapsed time from the start of the test. The ID generation unit 13b generates a serial number from the start of the test as identifier information (ID) for identifying each log.

  The log data generated by the log data generation unit 13 includes time information generated by the time generation unit 13a and identifier information generated by the ID generation unit 13b. The log data generation unit 13 may be configured to input simulation time information from the simulation time management unit 30. In this configuration, the log data generated by the log data generation unit 13 includes simulation time information in addition to the real time time information generated by the time generation unit 13a. Each process can be compared with the time in real time and the time in simulation time.

  The log data storage unit 14 is configured by a large-capacity storage medium such as an HDD (hard disk drive) or a flash memory, for example, and stores log data.

  The display control unit 15 generates a display screen for displaying the log, reads the log data from the log data storage unit 14 according to the operation content of the operation unit 17, and displays the log on the display unit 16 based on the information included therein. It is supposed to be displayed.

  The display unit 16 displays the log on the screen according to the control of the display control unit 15. The display unit 16 constitutes log data display means according to the present invention.

  The operation unit 17 includes an input device such as a keyboard, a dial, or a mouse, a display that displays test conditions, a control circuit that controls these, software, and the like. The input of each test condition and the display content of the display unit 16 To be set by the examiner.

  The UE simulator 100 includes an interface 101, a simulation calculation unit 104 having a layer processing unit 102 and a processing unit 103, and a processing time table 105. In the present embodiment, the simulation calculation unit 104 constitutes a UE communication function simulated by the UE simulator 100, and is assumed to be realized by a software program. The UE simulator 100 manages the above simulation time and adds time information at the simulation time to the IQ data when outputting IQ data corresponding to a predetermined communication standard to the base station simulator 1. To be sent to.

  The interface 101 has the same configuration as the interface 21 of the base station simulator 1, and transmits an IP packet including IQ data to the base station simulator 1 and receives an IP packet from the base station simulator 1. Yes. Note that, similarly to the base station simulator 1, the UE simulator 100 may include a reception buffer and a transmission buffer.

  Similar to the layer processing unit 41 of the base station simulator 1, the layer processing unit 102 is a PHY 102a that performs processing of the PHY layer, a MAC 102b that performs processing of the upper MAC layer, an RLC 102c that performs processing of the upper RLC layer, A PDCP 102d that performs processing of an upper PDCP layer and an RRC 102e that performs processing of an upper RRC layer are provided.

  The processing unit 103 generates a message to be transmitted to the base station simulator 1 and sends it to the layer processing unit 102, and processes a message received from the base station simulator 1 via the interface 101 and the layer processing unit 102. ing.

  In the processing time table 105, as shown in FIG. 3, the data type of the data calculated by the UE simulator 100 and the actual time required for the actual UE (completed UE) to process the data are associated in advance. It is a thing. The UE simulator 100 refers to the processing time table 105 when IQ data is generated, and adds time information at the simulation time as a time stamp to the IQ data based on the processing time corresponding to the corresponding data type.

  Here, the data type will be described. The data transmitted and received between the base station simulator 1 and the UE simulator 100 can be broadly classified into message data, control data, and user data. Some messages are transmitted and received at the start of communication and at the time of handover, for example. The control data includes retransmission control using, for example, ARQ (Automatic Repeat reQuest) or HARQ (Hybrid-ARQ). User data includes, for example, video data and audio data. Among them, message data and user data are processed in each layer (PHY layer to RRC layer) from the lowest layer to the highest layer of the layer processing unit. On the other hand, retransmission control by ARQ is executed in the RLC layer, and retransmission control by HARQ is processed in the MAC layer. As described above, the layer in which data is processed differs depending on the data type, and the processing time is different. The processing time also varies depending on the type of message and the content of user data. For this reason, the data type of data and the real time required for the actual UE to process the data are associated in advance.

  Next, an example of a log displayed by the display unit 16 will be described with reference to FIG.

  The display control unit 15 reads display target log data from the log data storage unit 14, creates display information for log display, and outputs the display information to the display unit 16. Thereby, the log display 60 illustrated in FIG. 4 is displayed on the display screen of the display unit 16.

  The log display 60 includes a log number display (No.) 61, a layer display (PHY, MAC, RLC, PDCP, RRC / TE) 62, a primitive type display (Primitive) 63, and a BTS (base station) number display (BTS) 64. , Channel information (Channel) 65, message name display (Message) 66, simulation time information display (Simulation Time) 67, and real time information display (Progress Time) 67.

  In the upper part of the log display 60, the logs of the respective processes are displayed in a time series in the time order of the simulation time information display 67 and the real time information display 68. Below the log display 60, a content display 69 indicating the data content of the designated log selected and highlighted by the tester or the like is displayed. At the lower end of the content display 69, actual data expressed in hexadecimal values is displayed.

  The log number display 61 is an information display for displaying a number for identifying a log of each process based on the ID information included in the log data. The layer display 62 is an information display that indicates the flow of primitive information (transmission source and destination layers) in the layer processing unit 41 based on the log data transmission source layer and destination layer by arrow lines. The primitive type display 63 is an information display indicating the type and name of the primitive based on the primitive name of the log data.

  The BTS number display 64 indicates the number of a base station that performs communication based on the BTS number of log data when the base station simulator 1 has a plurality of base station simulation operation units 40 to simulate the operations of the plurality of base stations. It is the information display which shows. The channel information display 65 is an information display indicating a channel for communication based on the channel information of log data. The message name display 66 is an information display indicating the names of messages transmitted and received between layers based on message description information in the communication data between layers of log data. The message name display 66 is omitted depending on the log data. The simulation time information display 67 is an information display indicating the time when data transmission / reception of each process is performed based on the simulation time information managed by the simulation time management unit 30. The real time information display 68 is an information display indicating the time when data transmission / reception of each process is performed based on the time information of log data.

  The column of the first row of the log display 60 shown in FIG. 4 (the log information of the number “132”) is the UE simulator 100 from the first base station at the simulation time “000.01.13.750” and the actual time “000.05.41.000”. In the channel of “LTE # DL # DTCH 0” (No. 0 of the downlink Dedicated Traffic Channel), “LTE # PDCP # DATA # REQ” (data request to PDCP) is transmitted from the RRC 41e to the PDCP 41d. ) Primitive processing is executed, and a message “RRC Connection Reconfiguration” (RRC connection redefinition) is transmitted.

  Next, operations of reception processing and transmission processing of the base station simulator 1 in the present embodiment will be described.

  First, the reception process of the base station simulator 1 will be described with reference to FIG.

  The interface 21 receives uplink data which is digital data of a baseband signal generated by the UE simulator 100 according to a predetermined communication standard (step S11). In the UE simulator 100, a time stamp is added to these uplink data with reference to FIG.

  The time stamp acquisition unit 31 reads the time stamp of the uplink data stored in the reception buffer 22a and acquires the time information of the uplink data (step S12).

  The simulation time management unit 30 gives an instruction (first instruction) for causing the base station simulation calculation unit 40 to perform reception calculation processing on uplink data on the condition that the time stamp acquisition unit 31 has acquired the time stamp. Notification is made (step S13).

  The base station simulation calculation unit 40 reads the uplink calculation target data from the reception buffer 22a, and performs reception calculation processing on the uplink data according to a predetermined communication standard (step S14).

  In the process of step S14, each communication data communicated between the five layers of PHY 41a, MAC 41b, RLC 41c, PDCP 41d, and RRC 41e included in the layer processing unit 41 is sequentially output to the log data generation unit 13, and log data The generation unit 13 generates log data. Then, the data from the layer processing unit 41 is transferred to the message processing unit 42, and predetermined processing is performed under the control of the scenario processing unit 12. When the process of step S14 ends, the process returns to step S11.

  Next, transmission processing of the base station simulator 1 will be described with reference to FIG. Here, description will be made assuming that the base station simulator 1 that has received uplink data from the UE simulator 100 transmits downlink data in response to the uplink data.

  Under the control of the scenario processing unit 12, the base station simulation calculation unit 40 performs transmission calculation processing according to a predetermined communication standard, and generates downlink data that is data to be transmitted to the UE simulator 100 (step S21). ).

  In the process of step S21, each communication data communicated between the five layers of RRC 41e, PDCP 41d, RLC 41c, MAC 41b, and PHY 41a included in the layer processing unit 41 is sequentially output to the log data generation unit 13, and the log data The generation unit 13 generates log data.

  The time stamp adding unit 33 adds a time stamp to the downlink data after the arithmetic processing (step S22). This time stamp is based on the time stamp of the uplink data transmitted by the UE simulator 100, the time in the reception calculation process of the uplink data, and the time in the transmission calculation process required when generating the downlink data. Time information in the simulation time. In other words, the elapsed time from when uplink data is received until the generation of downlink data is completed (when the base station simulator 1 performs processing in real time, the elapsed time is real time). This is the time added to the time stamp of the data. The downlink data to which the time stamp is added is output to the transmission buffer 22b.

  The transmission notification unit 34 notifies the interface 21 of an instruction (second instruction) for transmitting downlink data on condition that the time stamp adding unit 33 adds time information at the simulation time to the IQ data. (Step S23).

  The interface 21 reads the downlink data to be transmitted stored in the transmission buffer 22b, converts it into an IP packet, and transmits it to the UE simulator 100.

Next, the operation of the base station simulator 1 will be described using the timing chart shown in FIG. In this example, the UE simulator 100 transmits IQ data of IQ _A (0.003) to the base station simulator 1 as uplink data.

Here, the subscript A indicates a predetermined data type. The numerical value in parentheses indicates the time stamp in the simulation time. For example, IQ _A (0.003) indicates that IQ _A, which is IQ data of data type A, has time information of 0: 3 milliseconds as a time stamp.

  As described above, the data type and the actual time required for the actual UE (completed UE) to process the data are associated in advance by the table (see FIG. 3).

FIG. 3 shows that the actual UE processing time for data of data type A is 3 milliseconds in real time. If the UE simulator 100 starts processing the IQ data IQ _A of the data type A from the time “0” in the simulation time, the simulation time of the simulation time is not limited regardless of how many milliseconds it takes from the start of the processing to the end of the processing. Assuming that the processing is completed in 3 milliseconds, the IQ _A time stamp is set to (0.003).

When the interface 21 receives IQ _A (0.003) from the UE simulator 100, the interface 21 extracts IQ data stored in the payload portion of the IP packet. The extracted IQ data is sequentially and temporarily stored in the reception buffer 22a.

The time stamp acquisition unit 31 of the simulation time management unit 30 acquires time information (first time information) of IQ _A (0.003) stored in the reception buffer 22a.

Operation start notification unit 32, on condition that the time stamp obtaining section 31 acquires the time information of the _IQ A _(0.003), an instruction for causing the reception operation to the IQ A (0.003) (a 1 instruction) to the base station simulation calculation unit 40.

The base station simulation calculation unit 40 performs a calculation process of IQ _A (0.003), which is a target of the reception calculation process, from the reception buffer 22a, and gives an IQ _P indicating the result to the time stamp addition unit of the simulation time management unit 30 To 33.

The time stamp adding unit 33 includes the time stamp of the uplink data transmitted by the UE simulator 100, the time for the reception calculation process of the uplink data, and the time for the transmission calculation process required when generating the downlink data. Based on the above, a time stamp is added to IQ _P which is the downlink data after the arithmetic processing. Here, 5 milliseconds is added to the time stamp of IQ _{A, and} the time stamp of IQ _P is set to (0.008). Then, the time stamp adding unit 33 outputs the IQ _P to the transmission buffer 22b.

The transmission notifying unit 34 gives an instruction (second instruction) for transmitting the IQ _P that is downlink data on condition that the time stamp adding unit 33 adds the time information at the simulation time to the IQ _P. The interface 21 is notified.

The interface 21 reads the IQ _P to be transmitted from the transmission buffer 22b, converts it into an IP packet, and transmits it to the UE simulator 100.

Furthermore, the UE simulator 100 that has received IQ _P (0.008) performs processing for IQ _P , and performs processing for generating IQ _X that is uplink data in response thereto. Then, the UE simulator 100 refers to the processing time table 105 to obtain the processing time corresponding to these processes, adds this processing time to the time of the time stamp of IQ _P , and sets the time stamp of this time to IQ _X. It is added and transmitted to the base station simulator 1. Specifically, FIG. 7 is an example when the processing time (processing for IQ _P and generation processing of IQ _X ) is stored as 44 milliseconds in the processing time table 105, and the UE simulator 100 IQ _X (0...) Is data obtained by calculating time = 52 milliseconds by adding the processing time = 44 milliseconds to the time stamp time of IQ _P = 8 milliseconds and adding the time stamp of the calculated time. 052) is transmitted to the base station simulator 1.

  As described above, the base station simulator 1 in the present embodiment acquires the time information added by the UE simulator 100 from the transmission data stored in the reception buffer 22a based on the arithmetic processing time corresponding to the data type on the UE simulator 100 side. Then, calculation can be started to generate response data.

  Therefore, the base station simulator 1 in the present embodiment manages the simulation time different from the real time, so that even when testing a pseudo terminal that cannot perform a communication operation in real time, the tester determines whether the communication timing is appropriate. Can be evaluated.

  As described above, the test apparatus and the test method according to the present invention have the effect that the tester can evaluate whether or not the communication timing is appropriate even when testing a pseudo terminal that cannot perform a communication operation in real time. It is useful as a test apparatus and a test method for testing the operation of a communication function by communicating with a pseudo terminal that simulates the communication function of a mobile communication terminal that transmits and receives a radio frequency signal corresponding to a predetermined communication standard.

1 Base station simulator (test equipment)
12 scenario processing unit 12a scenario storage unit 13 log data generation unit (log data generation means)
14 log data storage unit 15 display control unit 16 display unit (log display means)
17 Operation part 21 Interface (transmission / reception means)
22 buffer section 22a reception buffer 22b transmission buffer 30 simulation time management section (management means)
31 TS acquisition unit (time information acquisition means)
32 Calculation start notification unit (calculation start notification means)
33 TS adding section (time information adding means)
34. Transmission notification unit (transmission notification means)
40 Base station simulation calculation unit (calculation means)
41 Layer processing unit 41a PHY (layer)
41b MAC (layer)
41c RLC (layer)
41d PDCP (layer)
41e RRC (layer)
42 Message Processing Unit 100 UE Simulator (Pseudo Terminal)

Claims (7)

A test apparatus (1) for communicating with a pseudo terminal (100) that simulates a communication function of a mobile communication terminal that transmits and receives a radio frequency signal in accordance with a predetermined communication standard, and tests the operation of the communication function. ,
The pseudo terminal is configured to manage a simulation time, which is a time in the operation of the communication function, which is different from the real time, and the data type of data to be transmitted to the test apparatus and the data to the mobile communication terminal Is provided with a processing time table previously associated with the actual time required for processing, and when transmitting data to the test apparatus, the processing time table is referred to at the processing start time of the data at the simulation time. and it has become the first time information is time in the simulation time plus the actual time required for the data is the transfer Dodori signal terminal for processing to transmit to said test apparatus,
Transmission / reception means (21) for transmitting / receiving digital data of a baseband signal to / from the pseudo terminal,
In accordance with the communication standard, the reception calculation process is performed on the uplink data which is the data received by the transmission / reception means from the pseudo terminal, and the transmission calculation process is performed according to the communication standard to transmit the data to the pseudo terminal. Calculation means (40) for generating certain downlink data and sending the generated downlink data to the transmission / reception means;
Management means (30) for managing the simulation time;
With
The management means includes
Time information acquisition means (31) for acquiring the first time information received by the transmission / reception means;
When transmitting the downlink data after acquiring the first time information, the time at the simulation time obtained by adding the calculation time of the reception calculation process and the transmission calculation process to the time of the first time information. Time information adding means (33) for generating certain second time information and causing the pseudo-terminal to transmit the generated second time information to the pseudo terminal;
A test apparatus characterized by comprising: The calculation means includes a plurality of layers in which each process is defined by the communication standard,
The test apparatus comprises:
Log data generating means (13) for generating log data of communication between predetermined layers of the arithmetic means;
Log display means (16) for displaying a log based on the log data;
Further comprising
The log data generation means generates the log data including time information at the simulation time,
The test apparatus according to claim 1, wherein the log display unit displays the log including time information in the simulation time. The log data generating means generates the log data including time information in the real time in addition to time information in the simulation time,
3. The test apparatus according to claim 2, wherein the log display means displays the log in which time information at the simulation time and time information at the real time are written together. A reception buffer (22a) for temporarily storing the uplink data received from the pseudo terminal by the transmission / reception means;
A transmission buffer (22b) for temporarily storing the downlink data transmitted by the computing means;
Further comprising
The management means includes
Computation for notifying the computation means of an instruction for performing the reception computation processing on the uplink data stored in the reception buffer on condition that the time information acquisition means has obtained the first time information. Start notification means (32);
Transmission notification means (34) for notifying the transmission / reception means of an instruction to transmit the downlink data stored in the transmission buffer on condition that the time information addition means has generated the second time information. When,
The test apparatus according to any one of claims 1 to 3, further comprising:   The test apparatus according to any one of claims 1 to 4, wherein the communication function of the pseudo terminal is realized by a software program.   The test apparatus according to any one of claims 1 to 4, wherein the communication function of the pseudo terminal is realized by a semiconductor integrated circuit. A test method for testing an operation of the communication function by communicating with a pseudo terminal (100) that simulates a communication function of a mobile communication terminal that transmits and receives a radio frequency signal corresponding to a predetermined communication standard,
The pseudo terminal is different from the real time, with adapted to manage a time of operation is the simulation time of the communication function, transmit to the mobile communication terminal and the data type of data to process has a processing time table that real-time and is associated in advance required to, when sending data, the data with reference to the processing time table in processing start time of the data in the simulation time is adapted to transmit the first time information is time in the simulation time plus the actual time required for the transfer Dodori signal terminal processing,
Receiving uplink data which is digital data of a baseband signal and the first time information from the pseudo terminal (S11);
Performing a reception calculation process on the uplink data according to the communication standard (S14);
Performing transmission calculation processing according to the communication standard to generate downlink data that is digital data of a baseband signal to be transmitted to the pseudo terminal (S21);
When transmitting the downlink data after acquiring the first time information, the time at the simulation time obtained by adding the calculation time of the reception calculation process and the transmission calculation process to the time of the first time information. Generating certain second time information (S22);
Transmitting the downlink data and the second time information to the pseudo terminal (S24);
A test method comprising:

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