JP4990329B2 - Network testing equipment - Google Patents

Description

  The present invention transmits a test data frame to a network device used for an IP network such as Ethernet (registered trademark), and when the transmitted data frame is received via the device under test, the device under test generates a fragment. The present invention relates to a network test apparatus for testing a reception state of a converted data frame.

  With the rapid development of communication technology and communication facilities in recent years, high performance of personal computers, etc. and the expansion and rapid spread of large-capacity data services (hereinafter referred to as “IP network”) Service) is rapidly increasing.

  For example, when Ethernet (registered trademark) is applied as a communication standard for an IP network, problems such as communication errors and transmission time delays occur. It is specified as byte). Therefore, when the amount of data exceeds the MTU, first, fragment processing is performed to finely divide the data frame for each fixed size, and the frame data is transmitted as information on the destination and transmission source (frame header). The fragmented frame data is transferred to the destination terminal in a divided state in the IP network, and is reconstructed at the destination terminal.

  In addition, with the rapid increase in IP network services, a network test apparatus (for example, Patent Document 1 below) for testing maintenance methods related to IP networks and network devices (routers, switching hubs, transmission apparatuses, etc.) as devices under test. Various ideas have been made.

JP 2004-320785 A

  By the way, as an evaluation test of a device under test used in an IP network, when a test data frame transmitted from a network test apparatus is received again via the device under test, a data frame fragmented by the device under test is received. The distribution frequency of the reception state information indicating the reception state may be obtained.

  However, when such a test is performed, all the reception state information during the target observation period must be temporarily stored in the memory, and the stored information must be analyzed, and if the target observation period becomes longer As a result, an enormous memory capacity for storing all the frame state information is required, and it takes a lot of time to analyze these data, and the test results cannot be grasped in real time.

  In addition, when data frames are transmitted from the network test apparatus to the device under test at equal intervals and the transmitted data frames are received again via the device under test, the frame interval of the data frames may fluctuate. However, in the conventional test apparatus, when the clock is asynchronous as the test contents of the device under test on the user side, the device under test absorbs the clock error and changes the transmission interval between frames (Inter Packet Gap: IPG). It was confirmed that it was sent back to the network test equipment, and it was not possible to observe whether the clock speed difference was affected.

  Furthermore, when data that exceeds the MTU of the IP network is transmitted, the device under test is divided into a plurality of data frames and transmitted, but the conventional test apparatus has only a counter for the number of bytes and the number of frames, When transmitting fixed-length data exceeding the MTU, it was impossible to check how much data each frame was fragmented. Therefore, even if the received data has the same rate of 100%, it has not been possible to confirm whether the short frame is 100% transmitted / received using a short IPG or the long frame is transmitted / received using a long IPG.

  Therefore, the present invention has been made in view of the above problems, and it is possible to reduce the storage capacity and the test time of information related to the test of the reception state of the data frame received via the device under test, and to reduce the time between frames. An object of the present invention is to provide a network test apparatus capable of knowing the distribution frequency of information such as a transmission interval and a frame length.

In order to achieve the above object, the network test apparatus according to claim 1 transmits a test data frame to a device under test, and transmits a frame between frames in the data frame received via the device under test. A network test apparatus 1 for displaying a distribution frequency of reception state information including at least information on the number of bytes of a transmission interval and information on the number of bytes of a frame length in the data frame in a predetermined display form,
A frame state information extraction unit 12 that extracts reception state information of the data frame as frame state information when the data frame is received via the device under test;
A distribution information selection unit 13 that selects, as distribution information, the frame state information to be tested among the plurality of extracted frame state information;
A distribution information processing unit 14 that distributes the distribution information for each preset resolution range and adds the distribution frequency of the distribution information distributed for each resolution range;
A storage unit 16 for storing a distribution frequency of the distribution information subjected to the addition processing in a table format created in advance;
A processing control unit 17 that controls display of the distribution frequency of the distribution information stored in the storage unit in a predetermined display form;
It is provided with.

The network test apparatus according to claim 2 is the network test apparatus according to claim 1, wherein the storage unit 16 includes two storage units.
When one storage unit is connected to the distributed information processing unit 14, the selector unit 15 controls switching the input / output path between each unit at a predetermined time so that the processing control unit 17 connects to the other storage unit. It is provided with.

  According to the network test apparatus of the present invention, arbitrary distribution information is distributed among the frame state information, which is the reception state information of the data frame received via the device under test, for each preset resolution range, and the first memory is stored. Since the count value, which is the distribution frequency information, is added and stored in the means and the second storage means, there is no need for a storage capacity for storing a huge amount of information as in the prior art, and the analysis time of the extracted distribution information is shortened can do. Further, it is possible to easily check whether or not the clock speed difference in the device under test is affected, and how much data each frame is fragmented.

  Further, the storage unit is configured by two storage units, and when one storage unit is connected to the addition processing unit, the input / output path between each unit is connected so that the other storage unit is connected to the processing control unit. Since the switching is alternately performed at predetermined time intervals, the distribution frequency count value addition processing in the distribution information and the distribution table and distribution frequency graph display control processing by reading the distribution frequency information can be simultaneously processed in real time. .

1 is a schematic block diagram showing a system configuration of a network test apparatus according to the present invention. (A)-(d) It is a conceptual diagram which shows the distribution information of the data frame used as the test object of the test apparatus. It is explanatory drawing which shows the example of switching control of the input output path in the selector part of the test apparatus. It is explanatory drawing which shows the example of distribution of the distribution information based on the distribution table for distribution in the test apparatus. It is explanatory drawing which shows the example of a distribution frequency graph display of the distribution information in the test apparatus.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings. The embodiment described in detail below is merely an example of the present invention, and is not intended to limit the present invention. Other embodiments and implementations that can be performed by those skilled in the art based on this embodiment will be described. Examples, operational techniques, etc. are all included in the scope of the present invention.

  The network test apparatus of this example uses a network device (router, switching hub, transmission apparatus, etc.) used for an IP network such as Ethernet (registered trademark) as a device under test, and a test data frame for the device under test. (When the frame length of the data frame is fixed and / or the transmission interval between frames (Inter Packet Gap: IPG) is a fixed value) and the transmitted data frame is received via the device under test, It is an apparatus for testing the reception status of data frames fragmented by a device.

  Then, the network test apparatus of this example extracts, as frame state information, reception state information including at least information on the number of bytes of the transmission interval between frames in the received data frame and information on the number of bytes of the frame length in the data frame. In this process, the frame state information to be tested is distributed as resolution information for each resolution range and the count value is added, and the distribution table is displayed and distributed based on the distribution frequency of the distributed distribution information. Display control processing such as graph display is simultaneously processed in real time.

[System configuration of the device]
First, the configuration of a network test apparatus according to the present invention will be described with reference to FIGS.

  As shown in FIG. 1, the network test apparatus 1 includes an operation input unit 11, a frame state information extraction unit 12, a distribution information selection unit 13, a distribution information processing unit 14, a selector unit 15, a storage unit 16, a processing control unit 17, A display unit 18 is provided. The network test apparatus 1 also includes an input / output unit 19 for transmitting and receiving data frames to and from a device under test through an IP network such as Ethernet (registered trademark).

  The operation input unit 11 includes, for example, an input device such as a keyboard or mouse having a numeric keypad or various setting keys, a display input device that operates a touch screen in which a position input device such as a touch pad is combined with an LCD or CRT screen, and the like. Is done. The operation input unit 11 is a test target among frame state information (arrival time information, latency information, IPG information, frame length information) that is reception state information of a data frame received via a device under test by a predetermined operation of the user. Item selection information for selecting frame state information as distribution information, distribution setting value desired by user for selected distribution information (offset value, resolution (μs or ms as time unit, number of bytes as data length)) In addition to the distribution distribution information used for distribution processing based on the resolution range for distribution for each resolution, various information necessary for using the network test apparatus 1 is input. Is output.

Here, the frame state information of the data frame to be tested by the network test apparatus 1 of this example will be described. As shown in FIGS. 2A to 2D, the frame state information of the data frame received via the device under test includes arrival time information, latency information, IPG information, and frame length information.
(Arrival time information)
As shown in FIG. 2A, the arrival time information is the following from the frame end between the frames when the data frame transmitted from the network test apparatus 1 to the device under test is received via the device under test. This is information obtained by measuring the time to frame end.
(Latency information)
As shown in FIG. 2B, the latency information is received for the data frame with the transmission time stamp when the data frame transmitted from the network test apparatus 1 to the device under test is received via the device under test. It is information on the time (Latency) from transmission to reception obtained by adding a reception time stamp to obtain the difference between the transmission time and the reception time.
(IPG information)
As shown in FIG. 2C, this is information on the number of IPG bytes between frames when a data frame transmitted from the network test apparatus 1 to the device under test is received via the device under test.
(Frame Length information)
As shown in FIG. 2D, this is information on the number of bytes of the frame length of each data frame when a data frame transmitted from the network test apparatus 1 to the device under test is received via the device under test. .

  The frame state information extraction unit 12 extracts and extracts the reception state information of the data frame received via the device under test as the above-described frame state information (arrival time information, latency information, IPG information, frame length information). Each frame state information is output to the distribution information selection unit 13.

  Based on the item selection information from the processing control unit 17, the distribution information selection unit 13 selects only the frame state information to be tested from the frame state information extracted by the frame state information extraction unit 12, and this selection The frame state information thus output is output as distribution information to the information distribution means 14a. That is, the distribution information selection unit 13 serves as a filter that selects only information necessary for the distribution table desired by the user from the frame state information extracted by the frame state information extraction unit 12.

  The distribution information processing unit 14 includes an information distribution unit 14a and an addition processing unit 14b, and distributes distribution information based on the distribution distribution information and counts the distribution frequency in the distributed distribution information with respect to the storage unit 16. The value is added.

  Based on the distribution distribution information from the processing control unit 17, the information distribution unit 14a stores the distribution information selected by the distribution information selection unit 13 in the first storage unit 16a and the second storage unit 16b described later. The distribution processing is performed by identifying which range of the resolution ranges in the distribution table for distribution is included. When the distribution information distribution process is completed, the information distribution unit 14a adds an area addition signal for adding the count value of the area corresponding to the resolution range of the distribution table for distribution including the distribution information. It is output to the processing means 14b. That is, the information distribution unit 14a distributes distribution information corresponding to the resolution range of the distribution distribution information set by the user for each resolution range when creating the distribution table of distribution information to be tested.

  When the addition processing means 14b receives the area addition signal from the information distribution means 14a, the added count signal of the distribution distribution table area stored in the first storage means 16a and the second storage means 16b is input signal. Addition processing (as the addition processing content, the count value stored in either the first storage means 16a or the second storage means 16b is read once, incremented with respect to that value, and then written back to the read storage means )It is carried out. In addition, the count value addition processing of the area in the distribution table for distribution is performed on either the first storage unit 16a or the second storage unit 16b connected at the time of switching according to the input / output path switching control by the selector unit 15. Processing is in progress.

  The selector unit 15 includes a writing selector unit 15a and an output selector unit 15b. As shown in FIG. 3, the addition processing unit 14b and the processing control unit 17 are the same storage unit (first storage unit 16a or In order to avoid simultaneous access to the second storage means 16b), the input / output path is alternately switched at predetermined time intervals (for example, at intervals of 1 second) based on the selector control signal from the processing control unit 17. That is, the selector unit 15 adds the count value of each area in the distribution distribution table of each storage unit 16a, 16b by the addition processing unit 14b and the count value of each area in the distribution data for distribution by the processing control unit 17. The input / output path is controlled so as to be processed by either one of the storage means for reading the distribution frequency information as information, and the count value addition process for the storage unit 16 and the distribution frequency information read display unit 18 are controlled. Both the display control processing for displaying the distribution table and the distribution frequency graph are realized in real time.

  The storage unit 16 is composed of, for example, a magnetic or optical storage medium or a semiconductor memory such as a ROM or a RAM, and includes a first storage unit 16a and a second storage unit 16b. The storage unit 16 stores item selection information and distribution distribution information set and input by the operation input unit 11, as well as control information of each unit constituting the network test apparatus 1. The first storage means 16a and the second storage means 16b store distribution distribution tables created based on the distribution distribution information. This distribution distribution table is a table for distribution information distribution based on the distribution distribution information described above, and an area is set for each resolution range, and the count value of the area corresponding to the distribution information is added by the addition processing means 14b. It is processed.

  Further, as shown in FIG. 3, since the count value addition process for the storage unit 16 and the distribution frequency information read process are performed simultaneously, the input / output paths of the first storage unit 16a and the second storage unit 16b are controlled by the selector unit 15. It is the structure which switches alternately for every predetermined time. Therefore, while the count value addition processing of the area in the distribution distribution table by the addition processing unit 14b is performed on one storage unit, the distribution control table 17 of the distribution distribution table by the processing control unit 17 is performed from the other storage unit. Processing for reading the count value as distribution frequency information is performed.

  For example, when the first storage means 16a and the addition processing means 14b are connected by the write selector means 15a as shown in the figure, the addition processing means 14b sends a distribution distribution table to the first storage means 16a. The count value addition processing for the corresponding area is performed. On the other hand, when the second storage unit 16b and the processing control unit 17 are connected by the output selector unit 15b, the processing control unit 17 performs the reading process of the distribution frequency information stored in the second storage unit 16b. Yes. When the input / output path is switched by the selector unit 15 after a predetermined time has elapsed, the processing contents for the first storage unit 16a and the second storage unit 16b are switched.

  Accordingly, the distribution frequency information stored in the first storage unit 16a and the second storage unit 16b is added to each of the first storage unit 16a and the second storage unit 16b by switching of the write selector unit 15a. By combining the distribution frequency information stored in the first storage means 16a and the second storage means 16b, it means that a distribution table of distribution information to be tested is completed.

  The processing control unit 17 is composed of, for example, a microcomputer including a CPU, ROM, RAM, and the like, and performs drive control of each unit constituting the network test apparatus 1. Further, when the distribution distribution information is set and input by the operation input unit 11, the processing control unit 17 outputs the distribution distribution information to the information distribution unit 14a. Furthermore, when the distribution distribution information is set and input by the operation input unit 11, the processing control unit 17 creates a distribution distribution table based on the distribution distribution information, and the first storage unit 16a and the second storage unit 16b. Further, when the item selection information is set and input by the operation input unit 11, the processing control unit 17 outputs this item selection information to the distribution information selection unit 13. Further, the processing control unit 17 selects a selector control signal for controlling the information distribution unit 14a and the processing control unit 17 to avoid simultaneous access to either the first storage unit 16a or the second storage unit 16b. To the unit 15.

  Further, the processing control unit 17 reads the count value of each area of the distribution data for distribution stored in the first storage unit 16a and the second storage unit 16b as distribution frequency information, and the read distribution frequency information is A display control signal for display control using a distribution table or distribution frequency graph (histogram display, line graph display, etc.) desired by the user is output to the display unit 18.

  The display unit 18 is composed of a display device such as an LCD or CRT, for example, and based on the display control signal from the processing control unit 17, the distribution frequency information of the distribution information stored in the first storage unit 16a and the second storage unit 16b. In addition to displaying a distribution table and various distribution frequency graphs based on the above, various display contents related to operations and settings necessary for driving the network test apparatus 1 are displayed.

  As a display example of a distribution table or distribution frequency graph related to the distribution frequency information displayed on the display unit 18, information on the IPG distribution between data frames as shown in the figure as distribution frequency information as shown in FIG. 1 byte, offset value: 0 byte distribution table, resolution: 1 byte, offset value: 1 byte distribution table, resolution: 2 byte, offset value: 1 byte distribution table, distribution frequency graph based on distribution frequency information as shown in FIG. There is a display such as a display (a histogram based on a distribution table with a resolution of 1 byte and an offset value of 0 byte in the figure).

[Device processing operations]
Next, the processing operation in the network test apparatus 1 described above will be described. Here, the processing operation when the distribution process of the IPG distribution of the data frame shown in FIG. 4 is performed using the distribution table of resolution: 1 byte and offset value: 0 byte will be described.

  First, the user sets the item selection information and the distribution distribution information by performing a predetermined operation on the operation input unit 11 in order to obtain a desired distribution table. Next, a test data frame (the frame length of the data frame is fixed and / or IPG is a fixed value) is transmitted from the network test apparatus 1 to the device under test, and the transmitted data frame is transmitted via the device under test. Receive.

  Next, the frame state information extraction unit 12 extracts frame state information (arrival time information, latency information, IPG information, frame length information) of the received data frame. Next, the distribution information selection unit 13 selects, as distribution information, frame state information related to the IPG selected by the user from the extracted frame state information based on the item selection information. Then, the information distribution means 14a distributes the selected distribution information based on the distribution frequency information, and adds the count value of the area corresponding to the resolution range of the distribution table for distribution including this distribution information. Output area addition signal.

  The addition processing unit 14b obtains the count value of the distribution distribution table area of the storage unit (for example, the first storage unit 16a) to which the input / output path is connected by the writing selector unit 15a from the information distribution unit 14a. Of the distribution distribution table stored in the storage means (for example, the second storage means 16b) on the side to which the input / output path is connected by the output side selector means. A process of reading the count value in each resolution range as distribution frequency information is performed. The read distribution frequency information is displayed as a distribution table as shown in FIG. 4 or as a distribution frequency graph as shown in FIG.

  As described above, in the network test apparatus 1 described above, a test data frame is transmitted to the device under test, and the transmitted data frame is extracted from the frame state information of the data frame received via the device under test. Then, frame state information based on the selection item information is selected as distribution information from the extracted frame state information. Then, the selected distribution information is distributed based on the distribution distribution information, the count value of the area corresponding to the resolution range of the distribution table for distribution is added, and each resolution of the stored distribution table is also determined. A count value in the range is read out as distribution frequency information, and a distribution table and a distribution frequency graph are displayed.

  As a result, only the distribution information selected by the user in the data frame received via the device under test is distributed, and the distribution frequency of the distribution information is count value added to the storage unit 16 as distribution frequency information. There is no need for a storage capacity for storing a huge amount of information as in the prior art, and the analysis processing time of the extracted distribution information can be shortened.

  Further, by extracting the IPG information as frame state information from the data frame received via the device under test, it is possible to observe whether or not the clock speed difference in the device under test is affected. Further, by extracting the frame length information as the frame state information from the data frame received via the device under test, it is possible to know the ratio of the number of bytes for each fragmented data frame, so the same rate of 100% However, it is possible to confirm whether the short frame is 100% transmitted / received by the short IPG or the long frame is transmitted / received 100% by the long IPG.

  Further, the storage unit 16 is composed of two storage units, a first storage unit 16a and a second storage unit 16b. When one storage unit and the addition processing unit 14b are connected, the other storage unit and the processing control unit are connected. 17 is used by alternately switching the input / output paths between the respective units every predetermined time so that the distribution frequency count value addition processing in the distribution information and the distribution table and distribution by reading out the distribution frequency information. The frequency graph display control process can be simultaneously processed in real time.

  By the way, in the form described above, the distribution frequency of the distribution information distributed based on the distribution distribution information is changed by changing the resolution and time range conditions set in the distribution distribution information as desired by the user, and in the distribution table for distribution It is also possible to adopt a configuration (detailed search function) in which distribution information in a specific range is sorted and displayed in more detail. With such a configuration, it is possible to know the detailed distribution frequency in a specific range in the initially set resolution range, and it is possible to perform a device test under test with higher accuracy.

  In the above configuration example, the distribution frequency information is stored by adding the count value of the area corresponding to the resolution range of the distribution table for distribution stored in the storage unit 16. There is no particular limitation as long as the distribution frequency information is counted for each resolution range set by the user and the counted distribution frequency information can be read.

DESCRIPTION OF SYMBOLS 1 ... Network test apparatus 11 ... Operation input part 12 ... Frame state information extraction part 13 ... Distribution information selection part 14 ... Distribution information processing part (14a ... Information distribution means, 14b ... Addition processing means)
15 ... selector section (15a ... selector means for writing, 15b ... selector means for output)
16: Storage section (16a: first storage means, 16b: second storage means)
17 ... Processing control unit 18 ... Display unit 19 ... Input / output unit

Claims (2)

Information on the number of bytes of the transmission interval between the frames in the data frame transmitted through the device under test, and information on the number of bytes of the frame length in the data frame received from the device under test A network test apparatus (1) for displaying a distribution frequency of reception state information including at least a predetermined display form,
A frame state information extraction unit (12) for extracting reception state information of the data frame as frame state information when the data frame is received via the device under test;
A distribution information selection unit (13) that selects, as distribution information, the frame state information to be tested among the plurality of extracted frame state information;
A distribution information processing unit (14) that distributes the distribution information for each preset resolution range and adds the distribution frequency of the distribution information distributed for each resolution range;
A storage unit (16) for storing a distribution frequency of the distribution information subjected to the addition processing in a table format created in advance;
A processing control unit (17) for controlling display of the distribution frequency of the distribution information stored in the storage unit in a predetermined display form;
A network test apparatus comprising: The storage unit (16) includes two storage units,
When one storage unit is connected to the distributed information processing unit (14), the process control unit (17) is controlled to switch the input / output path between each unit at predetermined time intervals so as to connect to the other storage unit. The network test apparatus according to claim 1, further comprising a selector unit (15) for performing the operation.

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