JP6517895B2 - Terminal test apparatus and terminal test method - Google Patents

Description

  The present invention relates to a terminal test apparatus and a terminal test method for testing a terminal.

  Nowadays, we connect all kinds of things such as electronic devices, chips and sensors to communication networks such as the Internet, and promote "Information of the Internet" to mutually control things by promoting information exchange, so-called IoT (Internet of Things) realization The movement of the In response to such a move, the 3rd Generation Partnership Project (3GPP) is an element specialized for IoT based on the so-called Long Term Evolution (LTE), which further accelerates the 3G mobile communication standard (3G). We are considering expansion of technology, network technology, etc. Patent Document 1 discloses a terminal test apparatus corresponding to such a specification.

  Various groups are considering terminals (UE; User Equipment) for various IoT services. In LTE, two UE categories are supported in Release 13 in order to realize further cost reduction, extension of coverage, and the like from Release 12 onward. One is category M1, and the other is NB (Narrow Band) -IoT category. In particular, the category M1 limits the transmission / reception bandwidth of the terminal to 1.08 MHz, and aims to reduce the cost of the UE chip (non-patent documents 1 and 2).

JP, 2017-69905, A

ETSI TS 136 101 V 13.5.0 (2016-12), http://www.etsi.org/deliver/etsi#ts/136100#136199/136101/13.05.00#60/ts#136101v130500p. Pdf New Technology to Enable IoT in LTE Release 13, NTT DoCoMo Technical Journal, Vol. 24, No. 2, https://www.nttdocomo.co.jp/binary/pdf/corporate/technology/rd/technical#journal/ bn / vol24 # 2 / vol24 # 2 # 009jp.pdf

  The category M1 transmits broadcast information (SIB; System Information Block) including the position number and the like of the terminal used in the previous LTE from the base station and the terminal test apparatus to the terminal at a specific timing. At this time, in order to monitor the broadcast information, the terminal does not transmit data (uplink of data) to the base station or the terminal test apparatus. Therefore, particularly in the terminal test, there is a risk that the terminal test apparatus may determine that there is an abnormality even if there is no particular problem with a terminal that does not perform uplinking of data at such timing.

  The present invention has been made in view of the above circumstances, and provides a terminal test apparatus and a terminal test method capable of smoothly performing a terminal test of the category M1.

The present invention is a terminal test apparatus that receives notification information and communicates with a terminal that monitors for a predetermined monitoring time, and performs a test of the terminal, wherein the terminal test apparatus is configured to receive the notification information. And the data transmitted from the terminal with a continuous time interval longer than the predetermined monitoring time , and the minimum unit of the continuous time interval is a multiple of one frame length of the data. It is .

Further, the present invention is a terminal test method for receiving notification information and performing communication with a terminal for monitoring for a predetermined monitoring time, and testing the terminal, wherein the notification information is transmitted to the terminal And receiving the data transmitted from the terminal with continuous time intervals longer than the predetermined monitoring time, and the minimum unit of the continuous time intervals is a multiple of one frame length of the data .

  According to the present invention, it is possible to receive and analyze data from the terminal at an appropriate measurement interval when testing the terminal, and to improve the accuracy of the determination regarding the terminal.

FIG. 1 is a conceptual block diagram of a terminal test apparatus according to an embodiment of the present invention. FIG. 2 is a conceptual diagram showing an aspect of indexing in each frequency band in LTE. FIG. 3 is a diagram showing scheduling of signals in one frame of category M1. FIG. 4 is a timing chart of scheduling showing exchange of data between the terminal test apparatus and the terminal in the conventional terminal test method. FIG. 5 is a timing chart showing an outline of a terminal test method according to an embodiment of the present invention. 6 (a) to 6 (d) are timing charts showing an outline of a terminal test method according to an embodiment of the present invention, and (a) to (c) are timing charts of reception data obtained from a normal terminal. And (d) is a timing chart of received data obtained from an incorrect terminal. FIGS. 7A and 7B are timing charts showing an outline of a terminal test method according to another embodiment of the present invention. FIG. 8 is a timing chart showing an outline of a terminal test method according to another embodiment of the present invention. FIGS. 9A to 9E are timing charts showing an outline of a terminal test method according to another embodiment, and are timing charts of reception data obtained from a normal terminal. FIGS. 10 (a) to 10 (c) are timing charts showing an outline of a terminal test method according to another embodiment, which is a timing chart of reception data obtained from an abnormal terminal.

  Hereinafter, a terminal test apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

  In FIG. 1, a terminal test apparatus 1 according to an embodiment of the present invention corresponds to, for example, the LTE standard, and transmits and receives radio signals to and from a terminal 2 by wire such as a coaxial cable as a pseudo base station. There is. The terminal test apparatus 1 may transmit and receive signals to and from the terminal 2 wirelessly via an antenna.

  The terminal test apparatus 1 includes a wireless signal processing unit 10, a wireless hardware control unit 11, a call processing unit 12, a wireless signal measurement unit 13, a user interface unit 14, and a control unit 15. There is.

  The wireless signal processing unit 10 transmits and receives a wireless signal to and from the terminal 2. The wireless signal processing unit 10 encodes transmission data of the call processing unit 12 and the wireless signal measurement unit 13 by coding, modulation, frequency conversion, and the like to generate and transmit a wireless signal. Further, the wireless signal processing unit 10 performs frequency conversion, demodulation, decoding, and the like on the wireless signal received from the terminal 2 and outputs the signal to the call processing unit 12 and the wireless signal measurement unit 13.

  The wireless hardware control unit 11 controls the wireless signal processing unit 10 to control the transmission / reception level and the frequency of the wireless signal.

  The call processing unit 12 is connected to the wireless signal processing unit 10 and the wireless hardware control unit 11, and is set in the wireless hardware control unit 11 according to the parameters set according to the test conditions and the parameters of component carriers such as the multiplexing method. The signal is transmitted to make the wireless signal processing unit 10 transmit a wireless signal that meets the test conditions. Further, the call processing unit 12 transmits / receives a radio signal to / from the terminal 2 through the radio signal processing unit 10, and performs a call connection with the terminal 2 conforming to the test condition as a component carrier. , And performs call control as a component carrier corresponding to test conditions. Further, the call processing unit 12 transmits a setting signal to the wireless signal processing unit 10 in accordance with the set parameters such as the multiplexing scheme, and causes the wireless signal processing unit 10 to transmit a wireless signal conforming to the test condition.

  The wireless signal measurement unit 13 is connected to the wireless signal processing unit 10, measures transmission / reception levels and throughputs of wireless signals transmitted and received by the wireless signal processing unit 10, and outputs the measurement result to the control unit 15. . The control unit 15 associates the measurement result from the wireless signal measurement unit 13 with time information and the like and stores it in a hard disk or the like, and causes the user interface unit 14 to display and output it at the request of the user or outputs it as a log to a file It is supposed to

  The user interface unit 14 includes an input unit 141 that receives an operation input from a user, and a display unit 142 that displays a parameter carrier setting screen of the component carrier, a measurement result of the wireless signal measurement unit 13, and the like. The input unit 141 is configured of a touch pad, a keyboard, a push button, and the like. The display unit 142 is configured of a liquid crystal display device or the like.

  The control unit 15 is configured by a computer unit (not shown) having a central processing unit (CPU), a random access memory (RAM), a read only memory (ROM), a hard disk drive, and an input / output port.

  Programs for causing the computer unit to function as the control unit 15 are stored in the ROM and the hard disk drive of the computer unit, along with various control constants and various maps. That is, when the CPU executes a program stored in the ROM and the hard disk device, the computer unit functions as the control unit 15.

  A wireless hardware control unit 11, a call processing unit 12, a wireless signal measurement unit 13, and a user interface unit 14 are connected to input / output ports of the control unit 15.

  In the present embodiment, the wireless hardware control unit 11, the call processing unit 12, and the wireless signal measurement unit 13 are respectively configured by a processor such as a DSP (Digital Signal Processor) programmed to execute each process. There is. Also, the wireless signal processing unit 10 is configured by a communication module.

  The control unit 15 transmits a setting signal to the wireless hardware control unit 11 based on the parameter set by the input operation by the input unit 141 according to the parameter setting screen displayed on the display unit 142, and the wireless signal processing unit 10 The frequency and multiplexing method of the radio signal to be transmitted and received are controlled to make the radio signal measurement unit 13 perform measurement. Further, the control unit 15 notifies the call processing unit 12 of the set parameter, and establishes communication of a component carrier adapted to the set parameter.

  Further, the control unit 15 transmits a signal to the wireless hardware control unit 11 and the call processing unit 12 in accordance with the instruction input to the input unit 141 to perform test call control and the like.

  The terminal 2 is a device capable of wireless communication with the terminal test device 1 and other devices, and is only a portable terminal carried by a moving person such as a smartphone or a cellular phone, or a mobile terminal installed in a mobile object such as a vehicle Also includes fixed terminals. Other examples of the terminal 2 include various smart meters such as an electric meter and a gas meter, sensors mounted on various infrastructures such as roads and water supplies, and chips, but the type and use thereof are not limited. In normal use, the terminal 2 communicates with the LTE base station or the like by LTE, but in the test of the communication operation of the terminal 2, it can communicate with the terminal test apparatus 1 operating as a pseudo communication station.

  Recently, the movement toward the realization of the "Internet of Things", so-called IoT, in which all things such as electronic devices, chips, sensors, etc. are connected to a communication network such as the Internet and mutual information is controlled to mutually control things ing. In response to this trend, 3GPP is considering extension of elemental technology, network technology, etc. specialized for IoT based on the so-called LTE that further accelerates the 3G mobile communication standard (3G). There is.

  Various groups are considering terminals (UEs) targeted for various IoT services. The terminal 2 in the present embodiment is intended for use as such a terminal. And, in LTE, two UE categories are supported in Release 13, which is a successor of Release 12, in order to realize further cost reduction, coverage extension, and the like. One is a category M1, and the other is an NB-IoT category. In particular, category M1 limits the transmission and reception bandwidth of the terminal to 1.08 MHz, and aims to reduce the cost of the UE chip.

  The category M1 transmits and receives signals using a part of 1.08 MHz of the LTE transmission and reception band. Corresponding to this, since the terminal of category M1 can receive only 6 PRB (Physical Resource Block) data corresponding to 1.08 MHz, it receives a downlink signal transmitted in a band wider than 6 PRB in the LTE band. I can not do it. Specifically, a downlink control channel PDCCH (Physical Downlink Control) for allocating a downlink shared channel PDSCH (Physical Downlink Shared Channel) to which broadcast information (SIB: System Information Block) including data, a position number of a terminal, etc. is mapped. Channel) can not be received, so that it is not possible to obtain LTE broadcast information.

  Therefore, in category M1, a downlink physical control channel (MPDCCH; MTC-PDCCH) for machine type communication (MTC) for allocating broadcast information etc. mapped in 6 PRBs to terminals of category M1 and category M1. Specialized broadcast information is newly defined. The MPDCCH is a channel for transmitting downlink control information (DCI).

  As is known, in LTE, the frequency bandwidth to be used can be selected from 1.4 MHz, 3 MHz, 5 MHz, 10 MHz, 15 MHz and 20 MHz. Here, when 1.4 MHz is selected as the frequency bandwidth to be used for category M1, as shown in FIG. 2, one allocatable frequency band can be allocated for category M1 communicating with 6 PRBs (= 1.08 MHz). Limited to In FIG. 2, the index 0 is assigned to the one frequency band.

  FIG. 3 shows data between the terminal test apparatus (base station) and the terminal in one frame of a radio frame for performing LTE signal transmission, ie, a section of 10 milliseconds (ms) when the frequency bandwidth is 1.4 MHz. FIG. 8 is a diagram illustrating scheduling for exchanging data. The terminal test apparatus transmits downlink data (downlink data) using MPDCCH (DCI) allocated for three times. After this, at intervals of 1 ms, the terminal transmits uplink data (uplink data) by the uplink shared channel PUSCH (Physical Uplink Shared Channel) allocated for three times in order to reply to the MPDCCH from the terminal test apparatus. . This scheduling is described in Table A.3 of 3GPP 36.521, which is defined for category M1. According to 2.2.1.1-1b.

  FIG. 4 is a timing chart of scheduling showing exchange of downlink data and uplink data performed between the terminal test device (base station) and the terminal based on the above-mentioned underlying scheduling. The signal of the expansion part A corresponds to the first half of one frame in FIG. 3, and the terminal test apparatus transmits (downloads) data by MPDCCH (DCI) assigned. On the other hand, the enlarged portion B corresponds to the second half of one frame in FIG. 3, and the terminal transmits (uploads) data using the assigned PUSCH.

  Furthermore, according to 3GPP 36.508 that defines the category M1, the terminal test apparatus (base station) performs broadcast information (SIB) twice in a 40 ms period (10 ms × 2) in a period of 80 ms to the terminal. It is prescribed to send. Here, two pieces of broadcast information each having a length of 10 ms correspond to Si-WindowLength-BR-r13, Si-RepetitionPattern-r13, and Si-periodic of 3GPP 36.508, respectively. Unlike MPDCCH (DCI) sent to individual terminals, broadcast information is information to be broadcast (broadcast) to a plurality of terminals. The broadcast information includes the position number of the terminal, peripheral cell information, information for performing transmission restriction control, and the like, and is used from the conventional LTE, but the one specialized to the category M1 is newly defined.

  Along with the transmission of the broadcast information from the terminal test apparatus, the terminal receives and monitors the broadcast information over a predetermined monitoring time in a cycle of 80 ms. Therefore, in the scheduling as shown in FIG. 4, a terminal is dedicated to receiving and monitoring broadcast information, and a monitoring time T in which the upload data is not transmitted is inevitably generated periodically. Since each broadcast information has a length of 10 ms, that is, a length corresponding to one frame, this monitoring time T also has a length of at least one frame.

  In the case where the frequency bandwidth is 3 MHz, 5 MHz, 10 MHz, 15 MHz and 20 MHz, there are two or more frequency bands to be assigned (as shown in FIG. Data transfer by MPDCCH (DCI) and PUSCH, and transmission / reception of broadcast information can be allocated to different frequency bands, so upload data from the terminal as described above is transmitted Not time T does not occur.

  Here, assuming a terminal test scenario, conventionally, whether or not the terminal test apparatus can transmit (upload) data (generally, a specific number of frames (or the number of subframes)) (3GPP rules) Receive and measure / analyze the uploaded data signal, including the determination of whether or not In general, the terminal test apparatus receives and measures and analyzes a data signal every one frame (= 10 ms) of LTE data. Normally, in LTE data, one frame consists of 10 subframes (subframe length is 1 ms), and the terminal test equipment receives data from the terminal every 10 subframes. Become.

  Then, as described above, since the terminal receives broadcast information of 10 ms (one frame) in length, as indicated by the monitoring time T in FIG. 4, a situation where upload data is not generated periodically is at least 10 ms. Occur. This SIB monitoring time T (= 10 ms; 1 frame) has at least the same length as one frame (= 10 ms) of the measurement interval in the terminal test equipment. Therefore, even if the terminal is normal, the uplink data is not transmitted from the terminal at the measurement timing in the terminal test device that exactly matches the monitoring time T, and the terminal test device determines that there is no response signal. I will. That is, there is a risk that the terminal test apparatus may determine that the terminal is not normal with no response signal even for a normal terminal that is not particularly abnormal.

  Moreover, the conventional terminal test device receives data of a threshold strength higher than a predetermined level and measures the data. Such measurement is called power trigger measurement. According to this method, it is possible to always measure a section in which data having a specific strength or more exists, such as PUSCH (uplink data), but the terminal performs uplink data in a specific subframe among the number. It is difficult to measure whether it can transmit or the timing of subframes in which the terminal fails to transmit, and as a result, it is difficult to determine whether the terminal is operating according to 3GPP scheduling. It is. In addition, when the strength of data transmitted from the terminal is set near the minimum value, there are many cases where the power level difference between the noise level and the data is not sufficient when measuring uplink data, and the trigger to start measurement is Problems can arise such that the signal can not be measured without delay.

  FIG. 5 and FIG. 6 are schematic diagrams of the terminal test method implemented by the terminal test apparatus 1 according to the embodiment of the present invention, and realize the solution of the problems as described above. In the terminal test method according to the present embodiment, as shown in FIG. 5, the terminal test apparatus 1 can set the time in one measurement interval to, for example, two frames (10 ms × 2 = 20 ms) from the conventional one frame (= 10 ms). To increase). This measurement interval is the minimum time unit in the measurement of this embodiment, and corresponds to a time longer than the monitoring time T (= 10 ms) of the broadcast information (SIB) of FIG. That is, although the terminal 2 monitors the broadcast information over a predetermined monitoring time T, the terminal test apparatus 1 at least has a continuous time interval T1 (= 20 ms) which is a continuous time interval longer than the monitoring time T. Receive the data sent from 2.

  As a result, as shown in FIG. 6, the terminal test device 1 receives the signal (PUSCH) from the terminal 2 at a measurement interval (continuous time interval T1) for two frames, and there is no problem or a problem with the terminal 2 ( It is determined whether or not the 3GPP scheduling is in accordance. In particular, based on the pattern of the signal (PUSCH) displaying the corresponding result, the wireless signal measurement unit 13 of the terminal test device 1 determines that there is no problem or there is a problem, and outputs the result to the control unit 15. The control unit 15 causes the display unit 142 to display and output the measurement result from the wireless signal measurement unit 13.

  In the example of FIGS. 6 (a) to 6 (c), the terminal test device 1 obtains the PUSCH from the terminal 2 at a timing other than the monitoring time T of the broadcast information, and there is no problem with the terminal 2 (PASS). The case is shown. In the example of FIG. 6A, the terminal test device 1 obtains the PUSCH from the terminal 2 at continuous time intervals of timing that does not overlap the monitoring time T of the SIB at all. In the example of FIGS. 6B and 6C, the terminal test device 1 obtains the PUSCH from the terminal 2 at continuous time intervals of timing in which the monitoring time T of the SIB overlaps with only one frame.

  When the above pattern is obtained, the wireless signal measurement unit 13 determines that the signal according to the 3GPP scheduling is obtained from the terminal 2 (no problem), and the control unit 15 causes the display unit 142 to transmit the determination result. The output unit 142 outputs the corresponding result.

  On the other hand, in the example of FIG. 6D, the terminal test device 1 does not obtain PUSCH from the terminal 2 at timing other than the monitoring time T of the broadcast information, and the terminal 2 has a problem (FAIL) and is abnormal The case is shown. That is, the terminal 2 does not transmit (upload) data even at timings other than the monitoring time T of the broadcast information, and some abnormality has occurred in the terminal 2 (the terminal is not operating according to the 3GPP scheduling) )It is shown that.

  That is, the terminal test device 1 receives the data (PUSCH) transmitted from the terminal 2 at continuous time intervals T1 which is continuous time intervals longer than the monitoring time T of the broadcast information in the terminal 2. Thus, the terminal test device 1 correctly determines whether data other than the broadcast information is transmitted from the second terminal, regardless of whether the specific continuous time interval T1 overlaps with the monitoring time T of the broadcast information. It can be grasped.

  In the above embodiment, the continuous time interval T1 is defined by a multiple n of one frame length of data (for example, 3 times, 4 times,... N times). However, the continuous time interval T1 may be defined by a multiple of the subframe length of data (for example, 25 times, 30 times, etc. of the subframe length), and a specific method of determining the continuous time interval T1. Is not particularly limited.

  FIG. 7 is a schematic diagram of a terminal test method performed by the terminal test device 1 according to another embodiment of the present invention. In the case of FIG. 7 (a), the patterns of FIG. 6 (c) and FIG. 6 (b) of the previous embodiment are continuous, and the terminal 2 is normal when two continuous time intervals T1 are individually viewed. It is. Therefore, the terminal test device 1 determines that the terminal 2 is normal.

  However, in the first continuous time interval T1 as shown in the pattern of FIG. 6 (c), there may be a case where the last PUSCH can not be received because the failure actually occurred in the terminal 2. In such a case, although it is originally necessary to determine that there is an abnormality in the terminal, a problem may occur in which the terminal test device 1 determines that the terminal 2 is normal.

  Therefore, as shown in FIG. 7B, in the present embodiment, the terminal test device 1 further increases the number of frames in the continuous time interval T1 from two frames, for example, and extends the measurement to three frames. On this basis, the terminal test device 1 determines whether the terminal is normal or not based on whether or not there is a section in which no signal is present for two or more frame lengths.

  FIG. 8 is a view similar to FIG. 5 for the previous embodiment, and the terminal test device 1 calculates the time in one measurement interval from the conventional one frame (= 10 ms) to three frames (10 ms × 3 =). We will increase it to 30 ms). In (a) to (e) of FIG. 9, in the present embodiment, the terminal test apparatus 1 obtains PUSCH from the terminal 2 at timings other than the monitoring time T of broadcast information, and there is no problem in the terminal 2 (PASS) , Shows a normal case. In (a) to (c) of FIG. 10, in the present embodiment, the terminal test device 1 does not obtain PUSCH from the terminal 2 at timings other than the monitoring time T of broadcast information, and there is a problem in the terminal 2 (FAIL ), Indicates a non-normal case.

  The existence of a section in which no signal exists has a length of 2 frames or more indicates that a signal is not obtained from the terminal 2 separately from the monitoring time T of the broadcast information which may be originally normal. Thus, the terminal test device 1 can more accurately determine whether the terminal 2 is normal. However, the present embodiment does not deny the preceding embodiment, and can be used properly depending on the situation. For example, if it is desired to minimize the measurement time until the result display, it is possible to measure in two frames, and to improve the reliability of the measurement result, it is possible to use properly to increase the number of frames.

  To summarize the above-described embodiment, the terminal test device 1 assumes that the monitoring time at the terminal 2 is X * 1 frame length (X is a positive integer) which is a multiple of one frame length. A continuous time interval T1 (T2) of (X + Y) * 1 frame length is set (Y is a positive integer). In particular, when the monitoring time at the terminal 2 is one frame long as in the embodiment, the terminal test device 1 sets a continuous time interval T1 (T2) of n frame length (n is a positive integer of 2 or more) Do. The user can freely set the continuous time interval T1 (T2) of the terminal test device 1 according to the situation. For example, it is possible to cope with a monitoring time determined by a combination of Si-Windowlength and Si-repetitionPattern that defines each of the two types of broadcast information described above.

  Further, the terminal test device 1 may be configured to be able to change the continuous time interval in ms units (for example, 1 ms unit of 1 subframe length) separately from the unit by the frame length described above.

  However, if the continuous time interval is too long, the probability that the terminal test device 1 will fail to receive data increases, and the measurement processing time also increases, so the continuous time interval should be an appropriate value according to the situation. It is desirable to set. For example, it is conceivable to set the continuous time interval to 80 ms or less, which is a transmission period of broadcast information in 3GPP 36.508.

  The display unit 142 of the terminal test device 1 can display the determination result of the quality of the terminal 2 by the analysis of the wireless signal measurement unit 13 in various expression forms.

  According to the present invention, particularly in testing a terminal using category M1, the terminal test apparatus receives and analyzes data from the terminal at an appropriate measurement interval. This makes it possible to suppress an erroneous determination of the terminal due to the notification information, and can improve the accuracy of the determination.

  In addition, the test program for conducting the test mentioned above is also included in this invention. Such a test program is stored in the ROM of the control unit 15 of the terminal test apparatus 1, a hard disk drive, or another storage device, and read and executed by the CPU.

  Although the various embodiments have been described above with reference to the drawings, it goes without saying that the present disclosure is not limited to such examples. It is apparent that those skilled in the art can conceive of various modifications or alterations within the scope of the claims, and it is naturally also within the technical scope of the present disclosure. It is understood. In addition, the components in the above-described embodiment may be arbitrarily combined without departing from the scope of the disclosure.

1 terminal test apparatus 2 terminal 10 wireless signal processing unit 11 wireless hardware control unit 12 call processing unit 13 wireless signal measurement unit 14 user interface unit 15 control unit 141 input unit 142 display unit

Claims (5)

A terminal test apparatus that receives notification information and communicates with a terminal that performs monitoring for a predetermined monitoring time, and that tests the terminal,
The terminal testing device is adapted to transmit the broadcast information to the terminal, with a continuous successive time intervals longer than the predetermined monitoring time, and receives data transmitted from the terminal,
The minimum unit of the continuous time interval is a multiple of one frame length of the data,
Terminal test equipment. The terminal test apparatus according to claim 1 , wherein
The monitoring time is X * 1 frame length (X is a positive integer),
The terminal test apparatus, wherein the continuous time interval is (X + Y) * 1 frame length (Y is a positive integer). The terminal test apparatus according to claim 2 , wherein
The monitoring time is one frame long,
The terminal test apparatus, wherein the continuous time interval is n frame lengths (n is a positive integer of 2 or more). The terminal test apparatus according to any one of claims 1 to 3 , wherein
Terminal test apparatus which determines the quality of the said terminal based on the pattern of the said data, and displays a determination result on a display part. A terminal test method for receiving notification information and communicating with a terminal that monitors for a predetermined monitoring time, and testing the terminal,
Wherein with the notification information transmitted to the terminal, with a continuous successive time intervals longer than the predetermined monitoring time, and receives data transmitted from the terminal,
The minimum unit of the continuous time interval is a multiple of one frame length of the data,
Terminal test method.