JP6672554B2 - Measuring device and measuring method - Google Patents

Description

  The present invention relates to a measuring device and a measuring method for measuring a device under test that operates based on, for example, a wireless LAN communication standard.

  Mobile terminals such as mobile phones and smartphones are required to be able to communicate large amounts of information such as image information at a high speed. For this purpose, a MIMO (Multiple Input Multiple Output) is used as a communication method between a base station and a mobile terminal. ) Method has been realized.

  As an apparatus for testing a mobile terminal of the MIMO system, for example, two series of synthesized signals Sa and Sb are generated from transmission information signals output in four series, and 2 × 2 synthesized signals Sa and Sb are generated. Patent Document 1 proposes a technique for equivalently configuring M × N by performing pseudo transmission path processing (see paragraphs 0039 and 0043, FIG. 1).

JP 2014-93758 A

  However, the conventional test apparatus described in Patent Literature 1 employs a MIMO scheme in which a signal equivalent to a signal transmitted through an M × N propagation path is generated in one apparatus and given to a test target. For example, as compared with a test apparatus employing a SISO (Single Input Single Output) method, the circuit structure is complicated and the apparatus cost has to be increased. Also, with the remarkable progress of today's wireless LAN high-speed technology, the number of antennas for test objects also tends to increase. In such a situation, the conventional test apparatus is not suitable for remodeling due to the complicated circuit structure, and not only cannot be flexibly handled, but also the cost of the apparatus increases even if remodeling is performed.

  The present invention has been made in order to solve such a conventional problem, and it is possible to realize the measurement of the device to be measured in the MIMO system with an inexpensive configuration, and to measure the device to be measured in which the number of antennas is changed. It is another object of the present invention to provide a measuring apparatus and a measuring method which can flexibly respond.

In order to solve the above problem, a measuring device according to claim 1 of the present invention includes an integrated control device (55), a plurality of SISO-type measuring devices , and a main measuring device (51A) and a sub-measuring device (51B). and a corresponding plurality of measuring instruments which form a), a measuring measurement apparatus for performing of the measuring apparatus 1 for performing communication by MIMO scheme without predetermined control by the central control unit (DUT1) (50), the integrated The control device is configured to send a command signal only to the main measuring device, and each of the measuring devices includes a signal processing unit (70A, 71A) (70B, 71B) for processing a signal of a single stream; A transmission / reception unit (72A, 72B) having a transmission unit (73A, 73B) and a reception unit (74A, 74B) for a single stream signal,
The main measuring device among the measuring devices is configured to transmit the respective transmitting units while synchronizing the transmitting operation timings of the transmitting units of the own measuring device and the sub -measuring device based on a command signal from the integrated control device. Connection control means (61A) for connecting each of the measuring instruments and the device under test by wireless LAN by transmitting the signals of the single stream, respectively, from the respective transmitting sections during connection of the wireless LAN. Receiving control means (62A) for receiving a response frame from the device under test to the measured frame by the respective receiving units while synchronizing the receiving operation timings of the respective receiving units of the own measuring device and the sub- measuring device. ) And analyzing the data of the header part of the response frame to identify the frame to be measured, and based on the frame to be measured, Measurement control means (63A, 63B) for measuring the transmission characteristics of the measuring apparatus has a configuration further comprising a, a.

  With this configuration, in the measuring apparatus according to claim 1 of the present invention, since the header portion of the frame transmitted from the device to be measured is of the SISO system, even the measuring equipment of the SISO system can decode and decode the data. The measurement frame can be specified. This makes it possible to measure the transmission characteristics of the device under measurement of the MIMO system using a plurality of measurement devices of the SISO system at a lower cost than in the case of using the measurement device of the MIMO system, and to change the number of antennas of the device under measurement. Also, by increasing or decreasing the number of SISO measurement devices, it is possible to flexibly cope with the measurement of the device to be measured.

  In the measurement device according to claim 2 of the present invention, the measurement control unit determines whether or not the response frame satisfies a specific condition, and the determination unit satisfies the specific condition by the determination unit. Notifying the device under test of a notification signal indicating that the response frame has been received at the transmission destination when it is determined that the notification signal is not transmitted when it is determined that the specific condition is not satisfied. It has a configuration including a signal processing unit (66A) and a measurement unit (75A) that measures measured data included in the response frame determined to satisfy the specific condition by the determination unit.

  With this configuration, the measuring apparatus according to claim 2 of the present invention can determine an arbitrary modulation scheme or coding rate by, for example, determining a combination of the modulation scheme and the coding rate in advance as a specific condition. Thus, the transmission characteristics of the device under test can be measured at low cost by using a plurality of SISO measuring instruments.

  The measuring device according to claim 3 of the present invention, wherein the receiving unit receives, as the response frame, a ping reply frame transmitted by the device under test according to a ping request frame, wherein the measuring unit includes: It has a configuration for measuring the measured data included in the ping reply frame.

  With this configuration, the measuring device according to claim 3 of the present invention can inexpensively convert the data to be measured included in the ping reply frame transmitted by the device to be measured in response to the ping request frame by using a plurality of SISO measuring devices. Can be measured.

  Also, in the measuring device according to claim 4 of the present invention, the receiving unit receives, as the response frame, a frame having any one of the IEEE 802.11n HT-mixed PPDU format and the IEEE 802.11ac VHT PPDU format. Wherein the determination unit determines whether or not the specific condition is satisfied, based on data of a header part in one of the formats.

  With this configuration, the measuring device according to claim 4 of the present invention determines that the frame is a ping reply frame for the ping request frame based on only the analysis result of the header part of the response frame having each format, and notifies the notification signal. This makes it possible to reduce the time required for measurement as compared to the case where the payload section following the header section is also analyzed before notifying the notification signal, and it is easy to maintain the wireless connection state with the device under test of the MIMO scheme. Become.

According to a fifth aspect of the present invention, there is provided a measuring method for measuring one device under test (DUT1) using the measuring device according to the first aspect and performing communication by a MIMO method without predetermined control by the integrated control device. a measuring method of performing the main measurement equipment 1 of the measuring device of the plurality of measuring instruments, measuring devices other than the main measuring device and setting step of setting each as a sub measuring device (S11), the integrated A command transmitting step (S12) in which the control device sends a command signal only to the main measuring device, wherein the main measuring device among the measuring devices is configured to transmit its own measuring device to the main measuring device based on the command signal from the integrated control device. voluntary measuring instruments and the sub measuring machine by while synchronizing the transmission operation timing of each of the transmission portion from said transmitting unit thereby transmitting a signal of said single stream each sub measuring instrument Wherein the connection control step of the device under test connected by wireless LAN (S14) and vessels, the response frame from the device under test relative to the measurement frame transmitted from the transmitting unit during the connection of the wireless LAN, a self A receiving control step (S16) in which each of the receiving units of the measuring device and the sub-measuring device synchronizes the receiving operation timing of each of the receiving units with each other, and analyzes data of a header part of the response frame by analyzing the data. A measurement control step (S17 to S20) of specifying a measurement frame and measuring a transmission characteristic of the device under test based on the frame under test.

  With this configuration, the signal measurement method according to claim 5 of the present invention uses a plurality of SISO measurement devices and uses a plurality of SISO measurement devices at a lower cost than a MIMO measurement device. Can be measured, and even if the number of antennas of the device under test is changed, it is possible to flexibly cope with the measurement of the device under test by increasing or decreasing the number of SISO measurement devices.

  The present invention can provide a measuring apparatus and a measuring method that can realize the measurement of the measured apparatus of the MIMO system with an inexpensive configuration and can flexibly cope with the measurement of the measured apparatus with the changed number of antennas.

It is a block diagram showing composition of a measuring device concerning one embodiment of the present invention. FIG. 2 is a hardware configuration diagram of a main measuring device and a sub-measuring device constituting the measuring device according to the embodiment of the present invention. It is a block diagram showing the functional composition of the control part of each of the main measuring equipment and the sub-measuring equipment which constitute the measuring device concerning one embodiment of the present invention. It is a figure showing the example of composition of the ping reply frame in the measuring device concerning one embodiment of the present invention. 5 is a flowchart illustrating transmission characteristic measurement processing of a device under test in the measurement apparatus according to the embodiment of the present invention. 5 is a flowchart illustrating an example of transmission / reception operation timing synchronization control of a main measurement device and a sub measurement device of the measurement device according to an embodiment of the present invention. FIG. 6 is a conceptual diagram showing a measurement processing image of a transmission characteristic of a device under test in the measuring device according to one embodiment of the present invention. It is a figure showing composition of a frame for measurement of a measuring device concerning one embodiment of the present invention. It is a figure showing composition of a frame for measurement of another example of a measuring device concerning one embodiment of the present invention.

  Hereinafter, an embodiment of a measuring device and a measuring method according to the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the measuring device 50 according to the present embodiment measures the DUT 1 by connecting to the DUT 1 as a device to be measured by a wireless LAN. In the present embodiment, for example, the measurement device 50 operates as a wireless LAN master device (AP: Access Point), and the DUT 1 operates as a wireless LAN slave device (STA: STAtion). The measurement device 50 communicates with the DUT 1 based on a communication standard based on IEEE 802.11n, IEEE 802.11ac, or the like.

  In the present embodiment, the measuring device 50 has two measuring devices 51A and 51B, a router 54, and an integrated control device 55. The measuring device 51A and the measuring device 51B are connected to an integrated control device 55 via a router 54 via a network 56 such as Ethernet (registered trademark).

  The integrated control device 55 is configured by, for example, a personal computer (PC). The integrated control device 55 communicates with the measuring devices 51A and 51B via the network 56 via the router 54, and controls the both devices in an integrated manner. Specifically, the integrated control device 55 sets one of the measuring devices 51A and 51B as a master (main measuring device) and sets the other as a slave (sub-measuring device), and also starts the measurement of the DUT1 with respect to the master. Control such as giving a command is performed. In FIG. 1, the measuring device 51A is referred to as a main measuring device (hereinafter sometimes referred to as a main measuring device 51A), and the measuring device 51B is referred to as a sub-measuring device (hereinafter referred to as a sub-measuring device 51B). Is shown as an example).

  In the present embodiment, the DUT 1 to be measured by the measuring device 50 performs communication of the MIMO system, and the number of antennas is, for example, two. On the other hand, the main measuring device 51A and the sub-measuring device 51B constituting the measuring device 50 each have a configuration for performing SISO communication.

  That is, the measurement apparatus 50 transmits two sets of information, ie, a single stream signal, modulated by the two SISO measuring devices 51A and 51B using a predetermined modulation method (for example, BPSK, QPSK, etc.). At the same time, the signals are transmitted from the antennas in parallel, and the DUT 1 receives the signals from the plurality of (two in this example) antennas as if they are information of the MIMO method, and receives the response frame in the MIMO method on the measuring device 50 side. The measurement of DUT1 is established by returning the data to.

  In addition, since the measuring devices 51A and 51B can transmit a single stream signal simultaneously and in parallel with each other, the main measuring device 51A among them transmits and receives the transmission / reception operation timing between the main measuring device 51A and the sub-measuring device 51B. Are synchronized with each other. Therefore, in the measuring device 50, the integrated control device 55 does not need to control the sub-measuring device 51B after giving the command to start the measurement of the DUT 1 to the main measuring device 51A. According to the configuration of the measuring device 50, communication with the DUT 1 by the MIMO method cannot be performed, but measurement of the DUT 1 of the MIMO method can be realized while transmitting and receiving information of two systems of the SISO method in parallel. As the measuring instruments 51A and 51B, it is assumed that a product such as MT8862A, which is a wireless LAN measuring instrument manufactured by Anritsu Corporation, is used.

  In the measurement device 50, the main measurement device 51A includes a control unit 60A, a transmission data generation unit 70A, a frame generation unit 71A, a transmission / reception unit 72A, a measurement unit 75A, and a display unit 76A. As shown in FIG. 2, for example, the main measuring device 51A is a microcomputer including a CPU 31, a ROM 32, a RAM 33, an input interface (I / F) unit 34 to which various interfaces are connected, and an output interface (I / F) unit 35. including. The main measuring device 51A executes a control program stored in the ROM 32 in advance, thereby causing the microcomputer to function as the above-described functional units of the main measuring device 51A.

  In the main measuring device 51A, the control unit 60A controls the entire main measuring device 51A and controls the sub-measuring device 51B to synchronize with the own measuring device. Control unit 60A is hereinafter referred to as main control unit 60A.

  The transmission data generation unit 70A generates transmission data set by the user and outputs the transmission data to the frame generation unit 71A.

  The frame generation unit 71A generates (configures) a frame including the data from the transmission data generation unit 70A, and outputs the frame to the transmission / reception unit 72A. The frame generation unit 71A constitutes a signal processing unit of the present invention together with the transmission data generation unit 70A described above.

  The transmission / reception unit 72A includes a transmission unit 73A and a reception unit 74A, and establishes a wireless connection with the DUT 1 based on, for example, a communication standard based on IEEE802.11ac. The transmission / reception unit 72A transmits / receives various data related to measurement to / from the DUT 1 after the wireless connection is established.

  Although not shown, the transmission unit 73A includes an encoding processing circuit, a modulation circuit, a DAC (digital-to-analog converter), an up-converter, a transmission antenna, and the like, and performs digital modulation and up-modulation on the frame generated by the frame generation unit 71A. Processing such as conversion is performed, and the data is transmitted to the DUT 1 via the antenna.

  Although not shown, the receiving unit 74A includes a receiving antenna, a down converter, an ADC (analog-to-digital converter), a demodulation circuit, a decoding processing circuit, and the like. Of the frames received from the DUT 1, the measurement control unit 63A described later performs The data to be measured of the measurement target is extracted from the frame determined to be the measurement target and output to the measurement unit 75A.

  Similarly, the sub measurement device 51B includes a control unit 60B, a transmission data generation unit 70B, a frame generation unit 71B, a transmission / reception unit 72B, a measurement unit 75B, and a display unit 76B. The control unit 60B controls the entire sub-measuring device 51B under the control of the main control unit 60A. Hereinafter, the control unit 60B is referred to as a sub control unit 60B.

  In the sub measurement device 51B, the transmission data generation unit 70B, the frame generation unit 71B, the transmission / reception unit 72B, the measurement unit 75B, and the display unit 76B are basically the same functional units in the main measurement device 51A, that is, the transmission data The generation unit 70A, the frame generation unit 71A, the transmission / reception unit 72A, the measurement unit 75A, and the display unit 76A have the same configuration. Here, the transmission data generation unit 70A and the frame generation unit 71A constitute a signal processing unit of the present invention.

  Similarly to the main measuring device 51A, for example, as shown in FIG. 2, the sub-measuring device 51B has a CPU 31, a ROM 32, a RAM 33, an input interface (I / F) section 34 to which various interfaces are connected, and an output interface (I / F). The microcomputer including the unit 35 is included. Also in the sub-measuring device 51B, the microcomputer is made to function as the above-described functional units of the sub-measuring device 51B by executing a control program stored in the ROM 32 in advance.

  In the measuring apparatus 50 shown in FIG. 1, the difference between the main measuring device 51A and the sub-measuring device 51B is that the former is the master and the transmitting portion 73A of the main measuring device 51A and the transmitting portion 73B of the sub-measuring device 51B. While performing control to synchronize the operation timing and performing control to synchronize the reception operation timing of the receiving unit 74A of the main measuring device 51A and the receiving unit 74B of the sub-measuring device 51B, the latter controls the synchronization as the slave by the former. Is to follow.

  In order to realize the above-described relationship between the master and the slave, the main control unit 60A controls the entire main measuring device 51A and also controls the sub-control unit 60B to provide a transmission synchronization trigger signal and a reception synchronization trigger signal. . The transmission synchronization trigger signal is a control signal for causing the sub-control unit 60B to perform a transmission operation by synchronizing the transmission unit 73B with the transmission unit 73A, and the reception synchronization trigger signal is generated when the sub-control unit 60B transmits the reception unit 74B to the reception unit 74A. This is a control signal for performing a receiving operation in synchronization with the control signal.

  Next, the configurations of the main control unit 60A and the sub control unit 60B will be described with reference to FIG. As shown in FIG. 3, the main control unit 60A includes a connection control unit 61A, a reception control unit 62A, and a measurement control unit 63A.

  The connection control unit 61A corresponds to each system from the transmission units 73A and 73B while synchronizing the transmission operation timing of the transmission units 73A and 73B of the main measurement device 51A and the sub measurement device 51B, which are self-measurement devices. By transmitting a signal of a single stream, connection control for connecting each of the measuring instruments 51A and 51B and the DUT 1 by a wireless LAN is performed.

  The reception control unit 62A transmits a response frame transmitted from the DUT 1 by the MIMO method in response to a measurement frame transmitted from each of the transmission units 73A and 73B during the wireless LAN connection to the main measurement device 51A and the sub measurement device 51B. While synchronizing the reception operation timings of the respective reception units 74A and 74B, the reception control for causing the reception units 74A and 74B to receive the signals is performed.

  The measurement control unit 63A causes the transmission frames 73A and 73B to transmit the measurement frames during connection of the wireless LAN, respectively, and receives the measurement frames by the reception units 74A and 74B of the main measurement device 51A and the sub measurement device 51B, respectively. The measurement control for measuring the characteristics of the DUT 1 based on the frame from the DUT 1 is performed. In the present embodiment, for example, the measurement control unit 63A analyzes the data of the header part of the response frame from the DUT 1 received by each of the receiving units 74A and 74B, specifies the frame to be measured, and Control for measuring the transmission characteristics of the DUT 1 based on.

  In order to enable the measurement of the transmission characteristics of the DUT 1, the measurement control unit 63A in the main measurement device 51A includes a data transmission control unit 64A, a determination unit 65A, a notification signal processing unit 66A, and a measurement instruction unit 67A as shown in FIG. Is configured.

  The data transmission control unit 64A causes the transmission data generation unit 70A and the frame generation unit 71A to generate a frame (measurement frame) including data (transmission characteristic measurement data) used for measuring the transmission characteristics of the DUT 1, The transmission unit 73A controls the DUT 1 to transmit. At this time, the measurement frame is also generated by the transmission data generation unit 70B and the frame generation unit 71B of the sub measurement device 51B by the above-described synchronization control of the connection control unit 61A, and is transmitted to the DUT 1 by the transmission unit 73B. In other words, the data transmission control unit 64A cooperates (synchronizes) with the data transmission control unit 64B of the measurement control unit 63B of the sub-measurement device 51B to transmit the measurement frames for one stream to the DUT 1 in parallel. To control.

  The determination unit 65A performs a process of determining whether or not the response frame transmitted from the DUT 1 to the measurement frame and received by the reception unit 74A of the main measurement device 51A satisfies a specific condition. At this time, the determination unit 65A fetches the result of the determination unit 65B of the sub-measuring device 51B determining whether the response frame received by the reception unit 74B satisfies a specific condition, and the result is received by the reception unit 74A. It may be added to the judgment index of the response frame.

  In the present embodiment, the frames (response frames) received by the receiving units 74A and 74B for measurement from the DUT 1 correspond to the ping (ping) request frames transmitted to the DUT 1 by the transmitting units 73A and 73B. Is a Ping Reply frame to be transmitted. This Ping reply frame has, for example, the configuration shown in FIG.

  That is, as shown in FIG. 4, the Ping reply frame received from the DUT 1 has a physical header and a data field. The physical header includes MCS index information.

  The data field includes an 802.11 header and 802.11 data. The 802.11 data includes an IP (Internet Protocol) header, an ICMP (Internet Control Message Protocol) header, Ping data, and an FCS (Frame Check Sequence).

  The ping data includes ping command data and transmission characteristic measurement data. The transmission characteristic measurement data includes, for example, data patterns such as “0000...”, “0101...”, And “1010...”. This is the data set by. By using these data patterns, the measuring apparatus 50 can grasp a data pattern in which an error is likely to occur in the evaluation of the transmission characteristics of the DUT 1.

  As described above, the frame received by the receiving units 74A and 74B of the main measuring device 51A and the sub-measuring device 51B from the DUT1 is a Ping reply frame, and the Ping reply frame includes the information of the MCS index. In this case, the determination unit 65A sets a value of the MCS index information (MCS index value) in advance for the process of determining whether or not the frames respectively received by the receiving units 74A and 74B satisfy a specific condition. It is assumed that the configuration is such that it is determined whether or not the value is the same value. As the MCS index value, for example, a value obtained by combining a modulation scheme and a coding rate can be set.

  The notification signal processing unit 66A, when the determination unit 65A determines that the above-described specific condition is satisfied, as a specific example, when the index value included in the Ping reply frame is a preset value, The DUT 1 is notified of a notification signal indicating that it has been received by the transmission destination, and performs processing of the notification signal so as not to notify the notification signal when it is determined that the specific condition is not satisfied.

  When the determining unit 65A determines that the response frame from the DUT 1 satisfies a specific condition, the measurement instructing unit 67A instructs the receiving unit 74A and the measuring unit 75A to measure the data to be measured included in the response frame. To instruct. The measurement unit 75A inputs the measured data output from the reception unit 74A based on the above instruction, and measures the transmission characteristics of the DUT 1 based on the measurement conditions set by the user.

  The main control unit 60A further includes a display control unit 68A. The display control unit 68A controls the display unit 76A to display the measurement result of the transmission characteristic of the DUT 1 by the measurement unit 75A. For example, as shown in FIG. 8, the display control unit 68 </ b> A displays the measurement results in a table format in which the horizontal axis represents time (t) and the vertical axis represents power (Power), and the relationship between the two is shown.

  In contrast to the main control unit 60A configured as described above, the sub control unit 60B includes a connection control unit 61B having the same functions as the connection control unit 61A, the reception control unit 62A, and the measurement control unit 63A in the main control unit 60A. , A reception control unit 62B and a measurement control unit 63B. Here, the connection control units 61A and 61B correspond to connection control means of the present invention. The reception control units 62A and 62B correspond to the reception control unit of the present invention, and the measurement control units 63A and 63B correspond to the measurement control unit of the present invention.

  The measurement control unit 63B in the sub-control unit 60B is equivalent to the data transmission control unit 64A, the determination unit 65A, the notification signal processing unit 66A, and the measurement instruction unit 67A of the measurement control unit 63A in the main control unit 60A. It has a unit 64B, a determination unit 65B, a notification signal processing unit 66B, and a measurement instruction unit 67B. Further, the sub control unit 60B is provided with a display control unit 68B equivalent to the display control unit 68A of the main control unit 60A. The main measurement device 51A and the sub-measurement device 51B also execute a control program stored in the ROM 32 in advance for the main control unit 60A and the sub-control unit 60B, so that the microcomputer (see FIG. 2) controls the main control unit 60A and the sub-control unit 60B. The sub-control unit 60B is made to function as each of the above-described functional units.

  Next, the operation of the measuring device 50 according to the present embodiment will be described with reference to FIGS.

  FIG. 5 is a flowchart illustrating the transmission characteristic measurement processing of the DUT 1 in the measurement device 50 according to the present embodiment. In this transmission characteristic measurement process, the DUT 1 first transmits a frame including the information of the reception MCS index = 7, and when the notification signal is not received, the value of the reception MCS index is decreased by one. I do. Further, it is assumed that the comparison MCS index = 5 (predetermined condition) is stored in advance in a storage unit such as the RAM 33 configuring the main control unit 60 </ b> A according to the setting of the user.

  In the transmission characteristic measurement process of the DUT 1 shown in FIG. 5, first, a process of setting a master (main measurement device) and a slave (sub measurement device) is performed (step S11). In this processing, the integrated control device 55 sends, for example, a command to the measurement device 51A via the network 56 to be the master. On the other hand, the measuring device 51A performs a process of setting its own measuring device as a master (main measuring device) based on the command. Thereafter, the main measuring device 51A recognizes its own measuring device as a master and the sub-measuring device 51B as a slave.

  Next, the integrated control device 55 sends a measurement start command to the main measurement device 51A (step S12).

  Upon receiving the measurement start command, the main measurement device 51A performs control for synchronizing the transmission and reception timings of the main measurement device 51A and the slave sub-measurement device 51B (step S13). In this control, for example, the main control unit 60A of the main measuring device 51A controls the driving of the transmission / reception unit 72A to the sub-control unit 60B of the sub-measuring device 51B in accordance with the timing to start measuring the transmission characteristics of the DUT1. To transmit a synchronization trigger signal. On the other hand, upon receiving the synchronization trigger signal, the sub control unit 60B controls the transmission and reception timing of the transmission and reception unit 72B to be synchronized with the transmission and reception timing of the transmission and reception unit 72A of the main measurement device 51A.

  In step S13, the transmission / reception of the main measurement device 51A and the sub measurement device 51B is performed by transmitting the synchronization trigger signal only once to the sub measurement device 51B in synchronization with the timing of starting the measurement of the transmission characteristics of the DUT 1. Although an example of synchronizing the operations has been described, the present invention is not limited to this. For example, as shown in FIG. 6, during the measurement of the DUT 1, a transmission synchronization trigger signal or a reception synchronization trigger signal is transmitted as necessary to sequentially May be synchronized.

  In the example illustrated in FIG. 6, the main measurement device 51A determines whether there is a transmission event that is any transmission processing during the measurement processing of the transmission characteristics of the DUT 1 by, for example, the main control unit 60A (in particular, the connection control unit 61A). It is determined whether or not it is (step S31). Here, when it is determined that there is a transmission event (YES in step S31), the main control unit 60A sends a transmission synchronization trigger signal to the sub measurement device 51B (step S32). Thereby, based on the transmission synchronization trigger signal, for example, the connection control unit 61A causes the sub measurement device 51B to change the transmission operation of the transmission unit 73B in the transmission / reception unit 72B by the transmission of the transmission unit 73A in the transmission / reception unit 72A of the main measurement device 51A. Control is performed so as to synchronize with the operation.

  When it is determined that there is no transmission event (NO in step S31), the main control unit 60A (particularly, the reception control unit 62A) determines whether there is a reception event which is any reception processing during the measurement processing. It is determined whether or not it is (step S33). Here, when it is determined that there is a reception event (YES in step S33), the main control unit 60A sends a reception synchronization trigger signal to the sub measurement device 51B. Thereby, based on the reception synchronization trigger signal, for example, the reception control unit 62B causes the reception control unit 62B to change the reception operation of the reception unit 74B in the transmission / reception unit 72B by the transmission of the reception unit 74A in the transmission / reception unit 72A of the main measurement device 51A. Control is performed so as to synchronize with the operation.

  When it is determined that there is no reception event (NO in step S33), and when the transmission simultaneous trigger signal is transmitted in step S32, the main control unit 60A repeatedly executes the processing from step S31. As described above, during the measurement of the DUT 1, the transmission synchronization trigger signal and the reception synchronization trigger signal are transmitted from the main measurement device 51A to the sub measurement device 51B each time, so that transmission and reception between the main measurement device 51A and the sub measurement device 51B are performed. The operation can be synchronized.

  Returning to FIG. 5, the transmission characteristic measurement processing will be described. In step S13, the main control unit 60A connects the main measuring device 51A and the sub-measuring device 51B to the DUT 1 by a MIMO wireless connection while controlling the transmission and reception timings of the main measuring device 51A and the sub-measuring device 51B. A wireless connection process for setting a state is performed (step S14). In this wireless connection process, the connection control unit 61A synchronizes the transmission operation timings of the transmission units 73A and 73B of the main measurement device 51A and the sub measurement device 51B, and responds to the respective systems from the transmission units 73A and 73B. By transmitting a signal of a single stream, control is performed so that each of the measuring devices 51A and 51B and the DUT 1 are connected by a wireless LAN.

  After the wireless connection processing in step S14, the data transmission control unit 64A controls the transmission unit 73A to transmit a Ping request frame as a measurement frame to the DUT 1 (step S15). At this time, the data transmission control unit 64B may also control the transmission unit 73B to transmit the Ping request frame to the DUT 1.

  Subsequently, the determining unit 65A determines whether or not the receiving unit 74A has received a Ping reply frame responding to the above-described Ping request frame as a response frame (step S16).

  If it is determined in step S16 that the Ping reply frame has not been received by the determination unit 65A, step S16 is repeated.

  On the other hand, when it is determined in step S16 that the Ping reply frame has been received, the determining unit 65A determines whether the value of the received MCS index is 5 (the value of the comparison MCS index) (step S16). S17). That is, the determination unit 65A determines whether the received Ping reply frame is a measurement target.

  If it is not determined in step S17 that the value of the reception MCS index is 5, the process returns to step S16. That is, at this time, the notification signal processing unit 66A performs processing so that a notification signal indicating that the frame has been received by the transmission / reception unit 72A is not transmitted to the DUT1.

  On the other hand, when it is determined in step S17 that the value of the reception MCS index is 5, the notification signal processing unit 66A controls the transmission unit 73A to transmit an ACK frame (notification signal) to the DUT 1 (step S18). .

  If it is determined in step S17 that the value of the reception MCS index is 5, the measurement instructing unit 67A instructs the receiving unit 74A and the measuring unit 75A to execute the measurement. Thereby, the receiving unit 74A extracts the data to be measured from the Ping reply frame for which the value of the received MCS index is determined to be 5 in step S17 (step S19), and outputs the data to the measuring unit 75A.

  The measurement unit 75A inputs the measured data from the reception unit 74A based on the above instruction, and performs the transmission measurement specified by the user (step S20).

  Further, the display control unit 68A displays the measurement result measured by the measurement unit 75A on the screen of the display unit 76A, for example, in a manner as shown in FIG. 8 (step S21).

  Next, the reception of the Ping reply frame and the return of the ACK frame (notification signal) in the measuring device 50 according to the present embodiment (see S16 to S18 in FIG. 5) will be described in more detail.

  Since both the main measuring device 51A and the sub-measuring device 51B constituting the measuring device 50 according to the present embodiment are of the SISO system, the communication of the MIMO system is maintained in the DUT1 when measuring the transmission characteristics of the DUT1. Need to behave as if In order to realize this, for example, the main measurement device 51A pays attention to the fact that the header part of the Ping reply frame (measured frame) is SISO data, and when receiving the Ping reply frame, analyzes only the header part. Is determined to be the frame to be measured. Based on this determination, the notification signal processing unit 66A immediately returns an ACK frame to the DUT1, thereby enabling the DUT1 to behave as if MIMO communication is established. I have.

  In the present embodiment, the frame to be measured transmitted by the DUT 1 is a MIMO signal, and is composed of a header section and a Payload section following the MIMO signal. Therefore, the entire packet cannot be decoded unless a plurality of streams are received. In this regard, in the present embodiment, since it is only necessary to measure the DUT 1 (the MIMO communication is not performed), it is determined from the analysis result of the header portion of the Ping reply frame that the ACK frame is determined as the measured frame. By returning the data, the measurement of the transmission characteristics of the DUT 1 can be reliably and promptly performed.

  The measurement result of the transmission characteristics of the DUT 1 using the Ping reply frame described above is displayed on the display unit 76A by the display control unit 68A, for example, in a manner shown in FIG. FIG. 7 shows the data structure of the Ping reply frame superimposed on the transmission characteristic in which the horizontal axis is the time value and the vertical axis is the transmission power value of DUT1.

  According to the above data structure, the measuring device 50 determines that the determining unit 65A of the main measuring device 51A is the Ping reply frame (measured frame) transmitted from the DUT 1 from the data of the header part of the Ping reply frame, At this point, it can be understood that the notification signal processing unit 66A transmits an ACK frame to the DUT 1 (see S18 in FIG. 4).

  FIGS. 8 and 9 show examples of frame formats that enable the return of an ACK frame as illustrated in FIG.

  FIG. 8 shows a configuration of the IEEE802.11n HT-mixed PPDU format. In this format, signals from L-STF to HT-SIG are transmitted as SISO signals. Therefore, the determination section 65A can decode the data in the SISO signal section (header section), and determines whether or not the above-described specific condition is satisfied based on the decoding result, that is, the MCS index value is set in advance. It can be determined whether or not the value has been set.

  FIG. 9 shows the configuration of the IEEE802.11ac VHT-PPDU format. In this format, L-STF to VHT-SIG-A are transmitted by SISO. Also in this case, the determination unit 65A can decode the data of the SISO signal section (header part), and determines whether or not the MCS index value is a preset value based on the decoding result. Can be.

  As can be understood from the description of FIGS. 7 to 9, the measuring apparatus 50 according to the present embodiment transmits a frame by the MIMO method and synchronizes the DUT 1 by synchronizing two independent SISO measuring devices 51A and 51B. Can establish a wireless connection state in which a frame can be returned by the MIMO method. Then, the timing at which the ACK frame is returned to the DUT 1 is determined by analyzing the header of the SISO method, so that the above-described wireless connection state is established from the measuring devices 51A and 51B, and the MIMO is performed between the DUT 1 and the DUT 1. The connection state is created to measure the transmission characteristics of the DUT 1.

  In the above-described example of the present embodiment, an operation example (see FIGS. 1 and 3) in which the measuring device 51A is set as a master (main measuring device) and the measuring device 51B is set as a slave (sub-measuring device) has been described. In the present invention, the master and the slave may be set to be switched. In order to realize this replacement, the control unit 60A of the measuring device 51A and the control unit 60B of the measuring device 51B need to have the same structure (see FIG. 3). Note that, for example, as shown in FIG. 1, when the measurement device 51B is used exclusively for the slave, the configuration of the measurement control unit 63B is reduced by removing the display control unit 68B and other unnecessary function blocks. The configuration may be more simplified than the measurement control unit 63A of the measurement device 51A.

  Further, in the above-described example of the present embodiment, an example is described in which the measuring device 50 is configured by the two measuring devices 51A and 51B of the SISO method. However, the present invention is not limited to this, and the measuring device 50 includes a plurality of measuring devices more than two. A configuration using equipment may be used. In the case of this configuration, for example, even when measuring the DUT1 having a larger number of antennas, the same number of measuring instruments as the number of antennas of the DUT1 are prepared, and the transmission / reception operation timing in the master-slave method is synchronized. By doing so, more flexible response is possible.

  As described above, in the present embodiment, the measuring device 50 has a plurality of measuring devices 51A and 51B of the SISO system, and each of the measuring devices 51A and 51B communicates with the DUT 1 performing communication by the MIMO system. The DUT 1 is measured by transmitting and receiving signals of a single stream in parallel.

  The measurement device 51A includes a transmission data generation unit 70A and a frame generation unit 71A, which are signal processing units for processing a single stream signal, and a transmission / reception unit 72A having a single stream signal transmission unit 73A and a reception unit 74A. The measurement device 51B has a transmission data generation unit 70B and a frame generation unit 71B which are signal processing units for processing a single stream signal, and a transmission / reception unit 72B having a single stream signal transmission unit 73B and a reception unit 74B. . One of the measurement devices 51A and 51B, for example, the measurement device 51A is set as a main measurement device, and the other measurement device 51B is set as a sub measurement device.

  In the measuring device 50, the main measuring device 51A synchronizes the transmission operation timings of the transmitting units 73A and 73B of the main measuring device 51A and the sub-measuring device 51B, and outputs a single stream from each of the transmitting units 73A and 73B. The connection control unit 61A that connects the DUT 1 to the main measurement device 51A and the sub measurement device 51B by transmitting a signal to the DUT 1 and a measurement frame transmitted from each of the transmission units 73A and 73B during the connection of the wireless LAN. A reception control unit 62A for receiving a response frame from the DUT 1 by the receiving units 74A and 74B while synchronizing the reception operation timings of the receiving units 74A and 74B of the main measurement device 51A and the sub measurement device 51B, Analyzes the data in the header of the response frame to identify the frame to be measured. Further comprising a measurement control section 63A for measuring the transmission characteristics of DUT1 based on the frame to be measured, a.

  With this configuration, in the measuring apparatus 50 according to the present embodiment, since the header part of the frame transmitted from the DUT 1 is of the SISO method, even the measuring equipment of the SISO method is decoded and is the frame to be measured. Can be identified. Therefore, the transmission characteristics of the MIMO DUT 1 can be measured using the SISO main measurement device 51A and the sub measurement device 51B at a lower cost than in the case of using the MIMO measurement device. Further, according to the configuration of the present embodiment, even if the number of antennas of the DUT 1 is changed, it is possible to flexibly cope with the measurement of the DUT 1 by increasing or decreasing the number of SISO measurement devices.

  In the measuring device 50 according to the present embodiment, the measurement control unit 63A determines that the response frame satisfies the specific condition by the determination unit 65A and the determination unit 65A determines that the specific condition is satisfied. In this case, a notification signal indicating that the response frame has been received by the transmission destination is notified to the DUT 1, and a notification signal processing unit 66A that does not notify the notification signal when it is determined that the specific condition is not satisfied, and a determination unit 65A And a measuring unit 75A that measures data to be measured included in the response frame determined to satisfy a specific condition.

  With this configuration, the measuring apparatus 50 according to the present embodiment determines the DUT 1 in an arbitrary modulation scheme or coding rate by, for example, previously determining a value obtained by combining a modulation scheme and a coding rate as a specific condition. Can be measured at low cost using the SISO main measurement device 51A and the sub measurement device 51B.

  In the measuring device 50 according to the present embodiment, the receiving units 74A and 74B receive a ping reply frame transmitted by the DUT 1 in response to the ping request frame as a response frame, and the measuring unit 75A transmits the ping reply frame to the ping reply frame. Measured data to be included is measured.

  With this configuration, the measuring device 50 according to the present embodiment can use the SISO main measurement device 51A and the sub-measurement device 51B to reduce the measured data included in the ping reply frame transmitted by the DUT 1 in response to the ping request frame. Can be measured.

  In the measuring device 50 according to the present embodiment, the receiving units 74A and 74B receive, as a response frame, a frame having any one of the IEEE 802.11n HT-mixed PPDU format and the IEEE 802.11ac VHT PPDU format. The determination unit 65A determines whether or not the above-described specific condition is satisfied based on the data of the header part in any of the formats.

  With this configuration, the measuring apparatus 50 according to the present embodiment can determine that the frame is a ping reply frame for the ping request frame based on only the analysis result of the header part of the response frame having each of the above formats and notify the notification signal. it can. As a result, in the present embodiment, it is possible to reduce the time required for measurement as compared with the case of notifying the notification signal after also analyzing the payload portion following the header portion in the ping reply frame, and to achieve wireless communication with the MIMO DUT1. Maintaining the connection state is also easy.

  As described above, the measurement apparatus and the measurement method according to the present invention can realize the measurement of the device under measurement of the MIMO system with an inexpensive configuration, and can flexibly cope with the measurement of the device under measurement with the changed number of antennas. The present invention is effective as a measuring device and a measuring method for measuring the transmission characteristics of a device to be measured in the MIMO system such as a mobile phone or a mobile terminal using a plurality of SISO measuring devices.

1 Device under test (DUT)
50 measuring equipment 51A SISO measuring equipment (main measuring equipment)
51B SISO measuring instrument (sub measuring instrument)
61A, 61B connection control unit (connection control means)
62A, 62B Reception control unit (reception control means)
63A, 63B Measurement control unit (measurement control means)
65A, 65B determination unit 66A, 66B notification signal processing unit 67A, 67B measurement instruction unit 70A, 70B transmission data generation unit (signal processing unit)
71A, 71B Frame generation unit (signal processing unit)
72A, 72B transmitting / receiving section 73A, 73B transmitting section 74A, 74B receiving section 75A, 75B measuring section

Claims (5)

Integrated control unit (55), and a corresponding plurality of measuring instruments which form a plurality of measuring instruments SISO scheme with the main measuring instrument (51A) of the sub-measuring device (51B), the integrated control communication by MIMO scheme a measurement measuring apparatus for performing of the measurement apparatus 1 to perform without a predetermined control by the device (DUT1) (50),
The integrated control device is configured to send a command signal only to the main measurement device,
Each of the measuring devices is
A signal processing unit (70A, 71A) (70B, 71B) for processing a signal of a single stream;
A transmission / reception unit (72A, 72B) having a transmission unit (73A, 73B) and a reception unit (74A, 74B) for the single stream signal, respectively.
The main measuring device among the measuring devices,
Based on the command signal from the integrated control device, by synchronizing the transmission operation timing of the transmission unit of each of the self-measurement device and the sub- measurement device, by transmitting the signal of the single stream from each of the transmission units by Connection control means (61A) for connecting each of the measuring instruments and the device under test by a wireless LAN;
A response frame from the device under test to the measurement frame transmitted from each transmitting unit during the connection of the wireless LAN is transmitted while synchronizing the reception operation timings of the receiving units of the self-measuring device and the sub- measuring device. Reception control means (62A) for receiving by each of the receiving units;
Measurement control means (63A, 63B) for analyzing the data of the header part of the response frame to identify the frame to be measured, and for measuring the transmission characteristics of the device to be measured based on the frame to be measured. A measuring device characterized by the above-mentioned. The measurement control means,
A determining unit (65A) for determining whether the response frame satisfies a specific condition;
When it is determined that the specific condition is satisfied by the determination unit, a notification signal indicating that the response frame has been received by the transmission destination is notified to the device under test, and it is determined that the specific condition is not satisfied. A notification signal processing unit (66A) that does not notify the notification signal when
The measuring device according to claim 1, further comprising: a measuring unit (75A) that measures measured data included in the response frame determined to satisfy the specific condition by the determining unit. The receiving unit is to receive a ping reply frame transmitted by the device under test in response to a ping request frame as the response frame,
The measuring device according to claim 2, wherein the measuring unit measures the measured data included in the ping reply frame. The receiving unit receives, as the response frame, a frame having one of an IEEE 802.11n HT-mixed PPDU format and an IEEE 802.11ac VHT PPDU format,
The measuring device according to claim 2, wherein the determination unit determines whether the specific condition is satisfied based on data of a header part in one of the formats. Using a measuring device according to claim 1, a measuring method for performing measurement of the measuring device 1 for performing communication by MIMO scheme without predetermined control by the central control unit (DUT1),
A setting step (S11) of setting one of the plurality of measuring devices as a main measuring device and a measuring device other than the main measuring device as a sub-measuring device;
A command transmission step (S12) in which the integrated control device sends a command signal only to the main measurement device;
The main measuring device among the measuring devices, based on a command signal from the integrated control device , the respective transmitting units while synchronizing the transmission operation timing of the transmitting unit of each of the own measuring device and the sub-measuring device said a voluntary measure device and the auxiliary measuring instrument by transmitting a signal of said single stream from each of the connection control step of connecting the device under test by the wireless LAN (S14),
A response frame from the device under test to the measurement frame transmitted from each transmitting unit during the connection of the wireless LAN is transmitted while synchronizing the reception operation timings of the receiving units of the self- measuring device and the sub-measuring device. A receiving control step (S16) of receiving each of the receiving units;
A measurement control step (S17 to S20) of analyzing a data of a header portion of the response frame to specify a frame to be measured, and measuring a transmission characteristic of the device to be measured based on the frame to be measured. Characteristic measurement method.

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