JPWO2020003393A1 - Logic analyzer - Google Patents

Abstract

To provide a logic analyzer that can execute processing according to the characteristics of the communication data to be analyzed. The logic analyzer detects from the communication data of serial communication an input module that inputs communication data of serial communication whose communication speed is changed in the middle of communication and a speed switching command for switching the communication speed used in serial communication. And a detection unit that detects a change in the communication speed of the serial communication based on at least one of the time of the pulse width of one pulse included in the pulse signal of the serial communication.

Description

The present disclosure relates to a logic analyzer that processes communication data.

Conventionally, there is a logic analyzer that switches a signal path for processing a digital signal to be analyzed (for example, Patent Document 1). The logic analyzer of Patent Document 1 includes a connection switching circuit for switching a signal path. The connection switching circuit switches the connection of a comparator that determines the logic level of the digital signal, a sampling circuit that samples the output signal of the comparator, and a large-capacity information storage device that stores the output signal of the comparator.

Japanese Unexamined Patent Publication No. 62-255883

By the way, there are various types of communication data to be analyzed by the logic analyzer. Therefore, the logic analyzer is desired to execute processing according to the characteristics of the communication data to be analyzed.

The present disclosure has been made in view of the above problems, and an object of the present disclosure is to provide a logic analyzer capable of executing processing according to the characteristics of communication data to be analyzed.

In order to solve the above problems, the first aspect of the present disclosure is to switch between an input module for inputting communication data of serial communication whose communication speed is changed in the middle of communication and a communication speed used in the serial communication. The change of the communication speed of the serial communication is changed based on at least one of the speed switching command being detected from the communication data of the serial communication and the time of the pulse width of one pulse included in the pulse signal of the serial communication. A logic analyzer including a detection unit for detecting is disclosed.

Further, as the second aspect of the present disclosure, communication data of a communication standard other than the RS-232C standard and the RS-485 standard is input, and the signal level of the communication data of the other communication standard is input. The driver circuit that executes conversion, the external interface, and the communication data of at least one of the RS-232C standard and the RS-485 standard are processed, and the signal level conversion is executed by the driver circuit. A logic analyzer including a processing circuit for outputting the communication data of the communication standard of the above from the external interface is disclosed.

According to the logic analyzer of the first aspect of the present disclosure, it is possible to execute processing such as starting storage of communication data in response to detection of a change in communication speed. As a result, processing can be executed according to the characteristics of the communication data to be analyzed.

Further, according to the logic analyzer of the second aspect of the present disclosure, communication data can be analyzed by the processing circuit for the RS-232C standard and the RS-485 standard. Further, for communication data of communication standards other than RS-232C standard and RS-485 standard, only signal level conversion processing can be executed and output from an external interface to an external device. As a result, processing can be executed according to the characteristics of the communication data to be analyzed.

It is a block diagram of the logic analyzer of this embodiment. It is a block diagram of the detection part of FPGA. It is a figure which shows the connection form of a logic analyzer. It is a figure which shows the connection form of the logic analyzer when the thru output part is used. It is a figure which shows the connection form of the logic analyzer of another example. It is a figure which shows the connection form of the logic analyzer of another example.

Hereinafter, an embodiment of the logic analyzer of the present disclosure will be described with reference to the drawings. FIG. 1 shows a block diagram of the logic analyzer 10 of the present embodiment. As shown in FIG. 1, the logic analyzer 10 includes various power supply circuits 11, an input module 13, an FPGA 15, a DDR memory 17, a non-volatile memory 19, and the like. The various power supply circuits 11 are circuits that function as a power supply for the logic analyzer 10. The various power supply circuits 11 include, for example, an AC / DC conversion circuit or the like, and receive electric power from a commercial power source or the like via the power supply connector 21. The various power supply circuits 11 supply the received power to various devices of the logic analyzer 10. The configuration of the power supply of the logic analyzer 10 is not particularly limited. For example, the logic analyzer 10 may be provided with a rechargeable battery, or may be configured to receive wireless power supply.

The input module 13 includes various interfaces for connecting to the device to be analyzed and the communication cable. The input module 13 includes RS-485 driver ICs 23 and 24, RS-232C driver IC25, CAN driver IC26, LVDS driver ICs 27 and 28, and a TTL input circuit IF (abbreviation of interface) 29. The type of IF included in the input module 13 is an example, and is appropriately changed according to the communication standard to be supported.

The RS-485 driver IC23 or the like is an interface for connecting to a device or the like (see FIG. 3) to be analyzed, which will be described later. The method of connecting the input module 13 and the device to be analyzed is not particularly limited. For example, the RS-485 driver IC23 or the like may be configured to include a connection portion (input connector or output connector) for bypassing the communication cable to be analyzed. Alternatively, the RS-485 driver IC23 or the like may be configured to include a probe, a glamper, or the like for connecting to the terminal of the device to be analyzed.

The RS-485 driver IC 23 is a driver circuit that performs communication conforming to the RS-485 communication standard, and can be connected to a two-wire RS-485 communication cable or the like that performs half-duplex communication. The RS-485 driver IC 24 is a driver circuit that performs communication conforming to the RS-485 communication standard, and can be connected to a 4-wire RS-485 communication cable or the like that performs full-duplex communication. The RS-232C driver IC 25 is a driver circuit that performs communication conforming to the RS-232C communication standard, and can be connected to, for example, a communication cable for three channels (communication lines). The CAN driver IC 26 is a driver circuit that performs communication conforming to the CAN (Controller Area Network) data communication standard, and can be connected to, for example, a communication cable for three channels (communication lines).

The LVDS drivers ICs 27 and 28 are interfaces that execute serial communication using LVDS (Low voltage differential signaling) technology. The LVDS driver IC 27 is an input interface, and has, for example, four input terminals (RX terminals). The LVDS driver IC 28 is an interface for output, and has, for example, four output terminals (TX terminals). The TTL input circuit IF29 is an interface for executing communication using Transistor-transistor-logic. The TTL input circuit IF29 converts the level of the input signal and outputs it to the FPGA 15. The TTL input circuit IF29 converts, for example, a signal having a power supply voltage (Vdd) of 5V into a signal of 3.3V and outputs the signal to the FPGA 15. The LVDS driver ICs 27, 28 and the TTL input circuit IF29 are interfaces for inputting a trigger signal instructing, for example, the start of analysis. The LVDS driver ICs 27 and 28 and the TTL input circuit IF29 may be used as an interface for inputting communication data to be analyzed. Further, the above-mentioned RS-485 communication, RS-232C communication, CAN communication, communication using LVDS technology, and communication using TTL are examples of the serial communication of the present disclosure.

The FPGA 15 includes, for example, a programmable logic device such as a Field Programmable Gate Array, a CPU, and the like. The FPGA 15 has a detection unit 31 and a reception unit 33 as circuit blocks. The FPGA 15 is an example of the processing circuit of the present disclosure. The FPGA 15 constructs a circuit block based on, for example, config information (configuration data) stored in the non-volatile memory 19. The processing circuit of the present disclosure is not limited to FPGA, and may be, for example, a programmable logic device (PLD) or a composite programmable logic device (CPLD). Further, the processing circuit of the present disclosure is not limited to a logic circuit such as FPGA, and may be an integrated circuit for a specific application such as ASIC. Further, the processing circuit of the present disclosure may be realized by software instead of hardware.

The detection unit 31 is a circuit block that analyzes communication data acquired via the input module 13, and detects the communication speed and the like. Note that the analysis of communication data is a concept that includes not only detection of communication speed but also detection of data, determination of data format, detailed analysis of data contents, and the like. The reception unit 33 is a circuit block that receives setting information for performing analysis. The method of accepting the setting information is not particularly limited. For example, the setting may be changed by receiving the config information via the JTAG connector 35 described later and changing the logic circuit of the FPGA 15, and receiving the setting information from the external device (PC51) via the LAN connector 37. You may change the setting. Alternatively, the method of accepting the setting information may be a method of reading the data preset in the config information stored in the non-volatile memory 19.

The DDR memory 17 is, for example, a DDR-SDRAM, and is used as a working memory in the processing of the FPGA 15. The working memory is not limited to DDR-SDRAM, and may be, for example, an SDRAM that uses one edge of the clock. The non-volatile memory 19 stores, for example, config information for constructing a circuit block of FPGA 15. The non-volatile memory 19 is, for example, a non-volatile memory such as EEPROM, FLASH memory, FRAM (registered trademark), and MRAM.

In addition to the input module 13, the logic analyzer 10 has a JTAG connector 35, a LAN connector 37, a USB connector 39, and an external interface 41 as interfaces for connecting to the outside. The JTAG connector 35 is connected to the FPGA 15. The JTAG connector 35 is, for example, a connector that executes communication conforming to the standard proposed by JTAG (Joint European Test Action Group). The FPGA 15 inputs config information and the like corresponding to the setting information to be analyzed via the JTAG connector 35.

The LAN connector 37 is connected to the FPGA 15 via the Ethernet PHY 43. The USB connector 39 is connected to the FPGA 15 via the USB PHY 45. The Ethernet PHY43 and the USB PHY45 are, for example, ICs that function as an interface between the logical layer and the physical layer of each communication standard. The LAN connector 37 is an interface for performing communication in accordance with the Ethernet (registered trademark) communication standard. The USB connector 39 is an interface for performing communication conforming to the USB standard. The Ethernet (registered trademark) standard is not particularly limited, but is, for example, a Gigabit Ethernet (registered trademark) standard. The USB standard is not particularly limited, but is, for example, a USB 2.0 standard or a USB 3.0 standard.

The LAN connector 37 is connected to the PC 51 via a LAN cable 47. The PC 51 is a personal computer, and includes, for example, a monitor, a keyboard, and a mouse. The PC 51 is a device for changing the setting information of the logic analyzer 10 and instructing the logic analyzer 10 to start analysis. Further, the PC 51 displays the data received from the logic analyzer 10 and the data received from the external logic analyzer 53 described later. As a result, the analyst who operates the PC 51 can confirm the analysis result. The logic analyzer 10 may display the analysis result on a monitor connected to the USB connector 39, for example.

The external interface 41 is connected to the FPGA 15. Further, the external interface 41 is connected to the external logic analyzer 53 via the connection cable 49. The external logic analyzer 53 analyzes various communication data. The type of communication standard that can be analyzed by the external logic analyzer 53 is not particularly limited. For example, the external logic analyzer 53 may have a configuration capable of analyzing communication data of a communication standard that cannot be analyzed by the logic analyzer 10. In this case, the FPGA 15 of the logic analyzer 10 may have a configuration capable of analyzing communication data of at least one of the RS-232C standard and the RS-485 standard, and may not be able to analyze the communication data of the CAN communication standard. Then, the external logic analyzer 53 may analyze the communication data of the CAN communication standard transferred by performing signal level conversion or the like with the logic analyzer 10, for example. Further, the external logic analyzer 53 may input the result of analyzing the communication data such as the RS-485 communication standard by the FPGA 15 and execute the process of displaying it on its own monitor.

The external interface 41 is, for example, an interface that executes communication using Transistor-transistor-logic. The external logic analyzer 53 has, for example, a channel for inputting a plurality of types of digital signals. The method of increasing the number of input channels is not limited to the method of increasing the number of physical terminals, but may be a method of increasing the number of communication ports realized by executing a program. The external interface 41 can output a plurality of types of digital signals to the external logic analyzer 53 via the connection cable 49, for example.

The PC 51 is connected to the external logic analyzer 53 via the USB cable 55. The PC 51 can acquire the data analyzed by the external logic analyzer 53 and display it on its own monitor.

Next, the configuration of the detection unit 31 of the FPGA 15 will be described with reference to FIGS. 2 and 3. FIG. 2 is a block diagram showing the configuration of the detection unit 31. As shown in FIG. 2, the detection unit 31 has a low-speed communication processing unit 61, a high-speed communication processing unit 62, and a common unit 63.

FIG. 3 shows an example of the connection form of the logic analyzer 10. In the connection example shown in FIG. 3, the logic analyzer 10 is connected between the servo amplifier 101 and the ABS (absolute type) encoder 102. The servo amplifier 101 executes commands such as output of position information to the ABS encoder 102. Further, the servo amplifier 101 executes feedback control for changing the power supplied to the servomotor 103 based on the position information acquired from the ABS encoder 102. As a result, the servo amplifier 101 can control the rotational operation of the servomotor 103 according to the position information.

Such a servo amplifier 101, an ABS encoder 102, and a servo motor 103 can be used as a drive mechanism for various working machines. The working machine referred to here is, for example, a component mounting machine for mounting electronic components on a substrate, a solder printing device for applying solder to a substrate, an articulated robot for assembling work, a machine tool for performing cutting, and the like. Further, the working machine is not limited to an industrial machine used in the FA (Factory Automation) field, and may be a nursing robot or the like. Therefore, the analysis target of the present disclosure can be various machines and devices that communicate data.

The servo amplifier 101 executes communication with the ABS encoder 102 by, for example, RS-485 standard communication using a communication protocol of HDLC (High-Level Data Link Control). Therefore, the logic analyzer 10 is connected to, for example, the RS-485 driver ICs 23 and 24 to the servo amplifier 101, the ABS encoder 102, the communication cable connecting the two, and the like to acquire communication data.

Here, it is assumed that the communication speed of the communication data to be analyzed is changed during the communication. Specifically, for example, the servo amplifier 101 executes low-speed communication when executing the initial setting for the ABS encoder 102. Further, for example, when the servo amplifier 101 completes the initial setting and determines that the ABS encoder 102 is a model compatible with high-speed communication, it executes acquisition of position information by high-speed communication. The low communication speed is, for example, 4 Mbps. High-speed communication is, for example, 8 Mbps.

When analyzing communication data whose communication speed is changed, the detection unit 31 can execute parallel processing by the low-speed communication processing unit 61 and the high-speed communication processing unit 62. Then, the detection unit 31 can more accurately determine the communication speed of the communication data by, for example, comparing whether the analysis results of the two processing units are correct. The low-speed communication processing unit 61 can analyze, for example, the communication data having a communication speed of 4 Mbps described above. The high-speed communication processing unit 62 can analyze communication data having a communication speed of, for example, 8 Mbps. The analysisable communication speed settings of the low-speed communication processing unit 61 and the high-speed communication processing unit 62 may be changed based on the setting information received by the reception unit 33. Further, the detection unit 31 may include processing units such as ultra-low speed, medium speed, and ultra-high speed in addition to the low-speed communication processing unit 61 and the high-speed communication processing unit 62. Further, the detection unit 31 may be configured to include only one of the low-speed communication processing unit 61 and the high-speed communication processing unit 62. In this case, the low-speed communication processing unit 61 or the high-speed communication processing unit 62 may automatically detect the communication speed by the communication speed automatic recognition unit 73, as will be described later. Further, the detection unit 31 may be configured to detect the communication speed in one processing unit and automatically change the sampling cycle or the like for sampling the communication data.

As shown in FIG. 2, the high-speed communication processing unit 62 analyzes high-speed communication as compared with the low-speed communication processing unit 61, but the processing block has the same configuration as the low-speed communication processing unit 61. Therefore, in the following description, the processing blocks of the low-speed communication processing unit 61 and the high-speed communication processing unit 62 will be described with the same reference numerals. The processing blocks with the same reference numerals execute the same processing except for the difference in communication speed, for example.

First, communication data is input to the detection unit 31 via the input module 13 (see FIG. 1). For example, the communication data transmitted from the servo amplifier 101 of FIG. 3 to the ABS encoder 102 and the communication data transmitted from the ABS encoder 102 to the servo amplifier 101 are input to the detection unit 31. The detection unit 31 can analyze the communication data input via the input module 13.

The communication data input to the detection unit 31 is input to each of the low-speed communication processing unit 61, the high-speed communication processing unit 62, and the common unit 63. The communication data input to the low-speed communication processing unit 61 and the high-speed communication processing unit 62 is transmitted in the order of the transmission line code analysis unit 71, the communication method-specific processing unit 72, and the communication speed automatic recognition unit 73. Next, the communication data output from the communication speed automatic recognition unit 73 is a command recognition and timer value setting unit (hereinafter, may be referred to as a setting unit) 74, a communication direction recognition and data separation unit (hereinafter, a recognition separation unit). There is) 75, and the FCS calculation unit 76 is transmitted in this order. The type and order of each processing unit is an example.

The transmission line code analysis unit 71 analyzes the coding method of the input communication data. The transmission line code analysis unit 71 analyzes which coding method, such as the NRZ (non-return-to-zero) method or the Manchester method, is used for the communication data. Further, the transmission line code analysis unit 71 may execute detailed analysis for classifying into each method such as the NZR (L) method and the NZR (I) method among the NRZ methods. The analysis method by the transmission line code analysis unit 71 is not particularly limited. For example, even if the transmission line code analysis unit 71 executes and analyzes high-level and low-level signal groups included in the communication data by performing pattern matching for determining whether or not the patterns match each method. good.

The communication method-specific processing unit 72 analyzes the communication method of the input communication data. The communication method-specific processing unit 72 analyzes, for example, which communication method such as the pace synchronization method or the synchronous communication method is used for the communication data. As a communication using the pace synchronization method, for example, there is a UART communication using a UART (Universal Asynchronous Receiver Transmitter). Further, as the communication using the synchronous communication method, for example, there is HDLC communication using HDLC. The analysis method by the processing unit 72 for each communication method is not particularly limited. For example, the communication method-specific processing unit 72 may analyze the communication method by detecting a specific bit string such as a flag sequence, a start bit, and a stop bit included in the communication data.

The communication speed automatic recognition unit 73 analyzes the communication speed of the input communication data. The communication speed automatic recognition unit 73 detects, for example, the communication speed with respect to the pulse signal of the input communication data based on the time of the pulse width of one pulse included in the pulse signal. The communication speed automatic recognition unit 73 detects, for example, the time from the rise to the high level to the fall to the low level as the pulse width time, and calculates the communication speed from the pulse width time. If the change time of one pulse can be detected, the change time of one bit can be detected. Therefore, the communication speed automatic recognition unit 73 can calculate the communication speed from the change time of 1 bit.

Further, the communication speed automatic recognition unit 73 may calculate the communication speed by using the analysis results of the transmission line code analysis unit 71 and the communication method-specific processing unit 72. For example, the communication speed automatic recognition unit 73 uses the width of one pulse when the start bit detected by the communication method-specific processing unit 72 is encoded based on the coding method detected by the transmission line code analysis unit 71. , The pulse width time may be detected. The communication speed automatic recognition unit 73 outputs the detected communication speed value to the trigger condition recognition unit 82 of the common unit 63 (see the broken line in FIG. 2).

The trigger condition recognition unit 82 can detect the change in the communication speed of the communication data to be analyzed based on the change in the communication speed value input from the communication speed automatic recognition unit 73. The trigger condition recognition unit 82 executes the process by using the detection of the change in the communication speed as a trigger. As shown in FIG. 2, the common unit 63 includes a data processing unit 83. The data processing unit 83 is a circuit block that executes data storage in the DDR memory 17 (see FIG. 1), reading data from the DDR memory 17, transferring data to another device, and the like. For example, for the ABS encoder 102 that performs the initial setting at a low speed and transfers the position information at a high speed, the trigger condition recognition unit 82 does not save the analysis result in the initial setting and analyzes only the position information at the time of high-speed communication. A command is issued to the data processing unit 83 to save the result. As a result, the data processing unit 83 can save only the communication data at the time of high-speed communication based on the command (trigger) input from the trigger condition recognition unit 82. The data processing unit 83 stores, for example, the communication data which is the analysis result in the DDR memory 17. Alternatively, the data processing unit 83 may transfer the analysis result to the external logic analyzer 53 or the PC 51. As a result, communication data (pulse waveform, etc.) during high-speed communication can be displayed on the PC 51 or the external logic analyzer 53 side.

Further, the detection unit 31 does not have to execute data storage or the like triggered by a change in communication speed. For example, the detection unit 31 may output the analysis result and the communication speed information to an external device. The external interface 41 of the present embodiment can output a plurality of types of digital signals via the connection cable 49. For example, the data processing unit 83 of the detection unit 31 outputs the communication data (position information, etc.) of the analysis result using one digital signal among the plurality of digital signals, and uses the other signals to determine the communication speed. Output information. That is, the data processing unit 83 outputs the communication speed information to the external logic analyzer 53 in addition to the analysis result.

According to this, the external logic analyzer 53 can execute not only the analysis result of the communication data input from the logic analyzer 10 but also the analysis and display using the information of the communication speed. For example, the logic analyzer 10 outputs the digital signal of the analysis result to the channel 1 of the external logic analyzer 53, and the logic analyzer 10 outputs the digital signal indicating the communication speed information to the channel 2 of the external logic analyzer 53. Then, the PC 51 connected to the external logic analyzer 53 or the external logic analyzer 53 may display the communication speed or the like based on the data acquired from the logic analyzer 10. Further, the external logic analyzer 53 may output the analysis result to the PC 51 only at high speed, for example.

Returning to FIG. 2, the setting unit 74 executes a command recognition process and a timer value determination process. Among the serial communications to be analyzed, it is assumed that a command for instructing speed switching (hereinafter, may be referred to as a speed switching command) is transmitted when the communication speed is changed in the middle of communication. The non-volatile memory 19 (see FIG. 1) stores, for example, bit value information of a speed switching command used in each communication standard. The setting unit 74 determines whether or not the speed switching command has been transmitted by referring to the bit value or the like stored in the non-volatile memory 19. When the setting unit 74 detects the speed switching command, it notifies the trigger condition recognition unit 82 of the detection (see the broken line in FIG. 2).

As a result, the trigger condition recognition unit 82 can detect a change in the communication speed of the communication data to be analyzed, as in the case where the communication speed value is input from the communication speed automatic recognition unit 73 described above. Specifically, for example, the trigger condition recognition unit 82 saves only the position information at the time of high-speed communication as an analysis result based on the detection information of the speed switching command input from the setting unit 74, and the data processing unit 83. You may issue a command to.

Further, the setting unit 74 may determine the response time of the speed switching command and detect an abnormality when the timeout time is reached. For example, the non-volatile memory 19 (see FIG. 1) stores reference information 91 in which the first time and the assumed data, which is the data to be detected after the lapse of the first time, are associated with each other. For example, as the communication speed switching process, there are cases where the speed change is executed immediately after receiving the speed switching command, and cases where the speed change is executed by receiving the next second stage command after receiving the speed switching command. is there. The first time and the assumed data corresponding to the processing sequence of such speed change are set in the reference information 91 in advance according to the communication standard and the like.

Therefore, the first time is, for example, the maximum time that can respond to the speed switching command or the second stage command transmitted after the speed switching command. In other words, when this first time elapses, the transmitting side recognizes it as a timeout. The assumed data is data assumed in a processing sequence such as a response command to a speed switching command, for example. Specifically, for example, the assumed data is a command that responds that the speed switching is completed, or a command that responds that the speed switching has failed. Further, for example, after the speed switching command is transmitted and the response command is transmitted, the speed may be switched from the transmission of the next second stage command. In this case, the time from the speed switching command to the response (switching completed) of the second stage command may be set as the first time.

Based on the reference information 91, the setting unit 74 detects an abnormality according to the fact that the assumed data cannot be detected from the communication data after only the first hour has elapsed from the detection of the speed switching command. For example, the setting unit 74 outputs to the trigger condition recognition unit 82 that an abnormality has been detected. As a result, the trigger condition recognition unit 82 can transfer the analysis result to the external logic analyzer 53 or the like in response to the detection of the abnormality, for example. Alternatively, the trigger condition recognition unit 82 can execute a process of storing the analysis result as a log at the time of abnormality in the data processing unit 83, a process of notifying the PC 51 of the detection of the abnormality, and the like.

Further, the setting unit 74 executes a timeout determination for commands other than the speed switching command included in the communication data. In the reference information 91 of the non-volatile memory 19 (see FIG. 1), in addition to the above-mentioned assumed data, a communication command used for serial communication to be analyzed and a timeout time of the communication command are set in association with each other. .. In the reference information 91, for example, a bit value that can identify each communication command is set as the data of the communication command. For example, in UART communication, since the processing time differs depending on the type of command, the timeout time for the command also differs. Therefore, the timeout time is set in the reference information 91 in advance for each type of command. For example, setting data in which the bit value of the command and the timeout time are described in CSV format may be created in advance on the PC 51 and saved from the PC 51 in the non-volatile memory 19.

The setting unit 74 detects a communication command from the input communication data based on the bit value of the communication command set in the reference information 91. The setting unit 74 sets the timeout time associated with the detected communication command based on the reference information 91. Then, the setting unit 74 detects an abnormality according to the fact that the response to the detected communication command cannot be detected by the time when the timeout time elapses after the communication command is detected. For example, the setting unit 74 outputs to the trigger condition recognition unit 82 that an abnormality has been detected. As a result, the trigger condition recognition unit 82 can output the analysis result to the external logic analyzer 53 or the like in response to the detection of the abnormality, for example.

In addition, the separation unit 75 recognizes the communication direction of the input communication data and separates the communication data according to the communication direction. Among the serial communications to be analyzed, not only full-duplex communication but also half-duplex communication in which the transmission direction is switched is assumed. For example, when half-duplex communication is executed between the servo amplifier 101 and the ABS encoder 102 in FIG. 3, the separation unit 75 includes communication data transmitted from the servo amplifier 101 to the ABS encoder 102 and servo from the ABS encoder 102. The communication data to be transmitted to the amplifier 101 is separated.

In the case of full-duplex communication, the logic analyzer 10 is connected to, for example, a communication line in each direction. Therefore, the separation unit 75 can separate the input communication line and the communication direction in a one-to-one correspondence. The method of determining the communication direction is not particularly limited. For example, the user may input the communication direction to the logic analyzer 10 as setting information. Alternatively, the separation unit 75 may analyze the content of the communication data and detect the communication direction. Specifically, when a command for performing initial setting and acquisition of position information to be transmitted from the servo amplifier 101 to the ABS encoder 102 is detected from the communication data, the separation unit 75 transmits the communication line from the servo amplifier 101 to the ABS encoder 102. It may be judged as a communication line in the communication direction toward.

Further, in the case of half-duplex communication, the communication direction is switched, for example, at regular intervals. Therefore, the separation unit 75 detects control information such as header information transmitted every half cycle in which the transmission direction is switched. Then, the separation unit 75 detects the cycle in which the control information is detected, that is, the half cycle in which the communication direction is switched. As a result, the separation unit 75 can detect the communication direction of the input communication data and separate the communication data according to the communication direction. The separation unit 75 outputs the communication data separated for each communication direction to the FCS calculation unit 76.

Further, the separation unit 75 outputs the detected communication direction information to the trigger condition recognition unit 82 (see the broken line in FIG. 2). As a result, the trigger condition recognition unit 82 can detect the switching of the communication direction in the communication data to be analyzed, similar to the notification from the communication speed automatic recognition unit 73 and the setting unit 74 described above. Then, the trigger condition recognition unit 82 can execute the process triggered by the switching of the communication direction. For example, the trigger condition recognition unit 82 can instruct the data processing unit 83 to store only the communication data transmitted from the servo amplifier 101 to the ABS encoder 102.

The FCS calculation unit 76 executes error detection and error correction for the communication data for each communication direction input from the separation unit 75. As described above, the reception unit 33 (see FIG. 1) of the FPGA 15 receives the setting information for performing the analysis. The reception unit 33 receives, for example, the communication direction of the serial communication to be analyzed, the type of the error detection code given to the communication data for each communication direction, and the threshold value for determining the number of times an error is detected by the error detection code. The reception unit 33 receives the setting information from the PC 51, for example, before starting the analysis.

The FCS calculation unit 76 detects an abnormality in the communication data corresponding to the communication direction received by the reception unit 33 according to the number of times of the threshold value of the error detection by the error detection code. Therefore, the FCS calculation unit 76 detects an error in each communication direction according to the condition received by the reception unit 33, and detects an error when the error is detected as many times (threshold value) as the condition is matched. For example, in serial communication of encoder information, an error code may not be added when a command requesting position information is transmitted, and an error code may be added only when the position information is transmitted (when responding). Therefore, the process of assigning an error detection code to the communication data may not be executed by bidirectional communication, but may be executed only by one-way communication. In such a case, the reception unit 33 determines, for example, the target communication direction, the type of error detection code (CRC code, parity code, etc.) assigned to the communication data in that communication direction, and the number of times of error detection. Accepts the threshold to judge. Then, when the FCS calculation unit 76 detects an error as many times as the threshold value received by the reception unit 33, it detects it as an abnormality.

As a result, for example, when the FCS calculation unit 76 detects an abnormality, it notifies the trigger condition recognition unit 82 to that effect. The trigger condition recognition unit 82 can execute a process (save, display, etc.) triggered by an abnormality notification, similar to the notification from the communication speed automatic recognition unit 73 or the like described above.

Further, the FCS calculation unit 76 outputs communication data for each communication direction to the data processing unit 83. As a result, the data processing unit 83 can save the communication data for each communication direction in response to an instruction from the trigger condition recognition unit 82 or the like. The FCS calculation unit 76 may not only detect the error but also correct the error and output the corrected communication data to the data processing unit 83. Further, the data processing unit 83 may be configured to store communication data that is not separated for each communication direction, that is, the acquired data as it is.

Here, as described above, the detection unit 31 includes a low-speed communication processing unit 61 and a high-speed communication processing unit 62, and can execute parallel processing by the two processing units. The detection unit 31 can determine the communication speed of the communication data by, for example, determining whether the analysis results of the two processing units are correct. For example, consider a case where the communication speed automatic recognition unit 73 of the low-speed communication processing unit 61 and the communication speed automatic recognition unit 73 of the high-speed communication processing unit 62 sample communication data based on preset setting information. In the case of low-speed communication, the communication speed automatic recognition unit 73 of the low-speed communication processing unit 61 can normally sample the communication data, while the communication speed automatic recognition unit 73 of the high-speed communication processing unit 62 cannot sample the communication data correctly. Therefore, the detection unit 31 can detect the communication speed of the communication data by determining whether the sampling results of the two communication speed automatic recognition units 73 are correct.

Further, as shown in FIG. 2, the common unit 63 has a through output unit 81. The through output unit 81 outputs, for example, communication data whose level has been converted by each driver IC of the input module 13 from the external interface 41 to the external logic analyzer 53. FIG. 4 shows a connection configuration when the through output unit 81 is used. As shown in FIG. 4, the logic analyzer 10 is connected between the host controller 104 and the servo amplifier 101. The host controller 104 is, for example, a control unit of a working machine whose drive source is a servomotor 103. The host controller 104 controls the servo amplifier 101 by CAN communication. In such a configuration, the logic analyzer 10 is used to analyze the CAN communication between the host controller 104 and the servo amplifier 101.

For example, the detection unit 31 of the logic analyzer 10 has a configuration capable of analyzing only the communication data of the RS-232C standard and the RS-485 standard communication standard. In this case, as described above, the detection unit 31 inputs communication data such as the RS-232C standard, and saves the communication data according to the communication speed.

In the example shown in FIG. 4, the detection unit 31 is configured so that the communication data of the CAN communication standard cannot be analyzed. On the other hand, the external logic analyzer 53 can analyze the communication data of the CAN communication standard transferred by performing signal level conversion or the like with the CAN driver IC 26 of the logic analyzer 10. The through output unit 81 shown in FIG. 2 outputs, for example, the communication data of the CAN communication in which the signal level conversion is executed by the CAN driver IC 26 from the external interface 41 to the external logic analyzer 53.

According to this, for the RS-232C standard and the RS-485 standard, the communication data can be analyzed by the detection unit 31. Further, for the communication data of the CAN communication standard (an example of other communication standards) other than the RS-232C standard and the RS-485 standard, only the signal level conversion processing is executed, and the external interface 41 to the external logic analyzer 53 Can be output to (an example of an external device). For example, communication standards such as CAN are different from RS-232C standards and RS-485 standards, and dedicated logic analyzers are sold. For this reason, the detection unit 31 analyzes the RS-232C standard and RS-485 standard that require original analysis, while the CAN communication standard on the market of the logic analyzer 10 is dedicated from the external interface 41. It can be output to the external logic analyzer 53 and analyzed. As a result, processing can be executed according to the characteristics of the communication data to be analyzed.

Further, the connection configuration to be analyzed is not limited to the configuration shown in FIGS. 3 and 4. FIG. 5 shows a connection mode of another logic analyzer 10. In the connection form shown in FIG. 5, the logic analyzer 10 is connected between the PC 105 and the linear scale 107, and analyzes communication data of UART communication (communication of RS-485 standard). The PC 105 is, for example, a maintenance terminal that controls the linear motor 109 and adjusts the speed based on the position information of the linear scale 107. By operating the PC 105, the user can execute the adjustment work for the linear scale 107 and the linear motor 109. In such adjustment work of the linear scale 107 and the linear motor 109, the analysis by the logic analyzer 10 may be executed. Further, the linear motor 109 can be used, for example, as a drive source for a mechanism for sliding the working machine. Therefore, the logic analyzer 10 can be used when adjusting the linear scale 107 and the linear motor 109 at the design stage of the working machine.

The logic analyzer 10 shown in FIG. 5 analyzes, for example, communication data conforming to the RS-485 standard, saves the data, and outputs the data. Further, as shown in FIG. 5, the PC 105 and the linear scale 107 are connected via the multiplex communication devices 110 and 111. The multiplex communication devices 110 and 111 are connected via, for example, an optical fiber cable, and perform time division multiplex communication. The multiplexing communication devices 110 and 111, for example, multiplex the communication data of the linear scale 107 with other data and transmit / receive it. In such a configuration, the logic analyzer 10 may analyze the communication data of the linear scale 107 before being multiplexed by the multiplexing communication device 111, for example. Alternatively, the logic analyzer 10 may analyze the communication data received from the PC 105 to the multiplexing communication device 111 and separated by the multiplexing communication device 111.

Further, as shown in FIG. 6, the logic analyzer 10 may be connected between the PC 105 and the multiplexing communication device 110. In the connection form shown in FIG. 6, the logic analyzer 10 is connected between, for example, the PC 105 and the linear scale 107, and analyzes the communication data of UART communication (communication of RS-232C standard).

The connection form and the configuration of the analysis target shown in FIGS. 3 to 6 are examples. For example, the logic analyzer 10 may analyze a plurality of communication data at the same time. For example, the logic analyzer 10 may simultaneously execute the analysis of the HDLC communication of FIG. 3 and the transfer of the communication data of the CAN communication of FIG. Further, the PC 105 shown in FIGS. 5 and 6 may be a controller for controlling a working machine or the like. That is, the logic analyzer 10 may be connected between the controller that controls the work machine and the like and the linear scale 107 controlled by the controller. Further, the communication data to be analyzed is not limited to the above. For example, the logic analyzer 10 may analyze communication data of an industrial network. The term "industrial network" as used herein refers to a relay or a relay using communication standards such as CC-Link (registered trademark), EtherCAT (registered trademark), MECHATROLINK (registered trademark) -III, and Profinet (registered trademark). It is a network that transmits control data that controls switches and the like. Further, the input module 13 may include an interface for converting between parallel communication and serial communication in addition to the signal level conversion.

Incidentally, RS-485 communication, RS-232C communication, CAN communication, communication using LVDS technology, and communication using TTL are examples of the serial communication of the present disclosure. The CAN driver IC 26 is an example of a driver circuit. The detection unit 31 is an example of a processing circuit. The external logic analyzer 53 is an example of an external device. Reference information 91 is an example of the first reference information and the second reference information.

As described above, according to the above-described embodiment, the following effects are obtained.
In one aspect of this embodiment, the detection unit 31 detects a speed switching command for switching the communication speed used in serial communication such as the RS-485 standard from the communication data by the setting unit 74, and then communicates in serial communication. Detect speed changes. Further, the communication speed automatic recognition unit 73 of the detection unit 31 detects a change in the communication speed of serial communication based on the time of the pulse width of one pulse included in the pulse signal of serial communication. The detection unit 31 may be configured to execute only one of the detection of the change in the communication speed by the speed switching command and the detection of the change in the communication speed by the pulse width.

According to this, in serial communication in which the communication speed is changed during the communication, the change in the communication speed can be detected. Then, the detection unit 31 can change the processing content of the analysis according to the detection of the change in the communication speed, for example. Specifically, the detection unit 31 can start saving the analysis result, for example, by using a change in the communication speed as a trigger. Further, the detection unit 31 may change, for example, the sample cycle for sampling the communication data of serial communication according to the communication speed. As a result, sampling can be performed appropriately. Then, the detection unit 31 can execute processing according to the characteristics of the communication data to be analyzed.

Here, in a general logic analyzer, only the communication speed is set before the analysis, and the sampling period and the like are not changed after the analysis is started. Therefore, in this kind of logic analyzer, there is a possibility that sampling cannot be performed properly after the analysis is started, that is, when the communication speed is changed in the middle of communication. On the other hand, the detection unit 31 of the present embodiment uses, for example, the processing results of the low-speed communication processing unit 61 and the high-speed communication processing unit 62 properly according to the communication speed, so that appropriate processing is performed according to the change in the communication speed. Can be executed.

Further, in one aspect of this embodiment, the detection unit 31 analyzes the communication data of the RS-232C standard and the RS-485 standard. The detection unit 31 may be configured to analyze communication data of at least one of the RS-232C standard and the RS-485 standard. Further, the CAN driver IC26 inputs communication data of a communication standard other than the RS-232C standard and the RS-485 standard (CAN data communication standard), and sets the signal level of the communication data of the CAN data communication standard. Perform the conversion. Then, the through output unit 81 of the detection unit 31 outputs the communication data of the CAN data communication standard obtained by executing the signal level conversion by the CAN driver IC 26 from the external interface 41 (see FIG. 4).

According to this, for the RS-232C standard and the RS-485 standard, the communication data can be analyzed by the detection unit 31. Further, for communication data of communication standards other than RS-232C standard and RS-485 standard, only signal level conversion processing is executed and output from the external interface 41 to an external device (external logic analyzer 53, etc.). it can. For example, the CAN data communication standard is different from the RS-232C standard and the RS-485 standard, and a general-purpose logic analyzer is commercially available. Therefore, communication data that requires original analysis such as RS-232C standard and RS-485 standard is analyzed by the logic analyzer 10, while other communication standards on the market for general-purpose logic analyzers are analyzed from the external interface 41. The communication data is output to an external logic analyzer 53 or the like for analysis. As a result, processing can be executed according to the characteristics of the communication data to be analyzed. The other communication standards disclosed in the present disclosure are not limited to CAN data communication standards.

It is needless to say that the present disclosure is not limited to the above embodiment, and various improvements and changes can be made without departing from the spirit of the present application.
For example, the detection unit 31 does not have to output the communication speed information.
Further, the detection unit 31 does not have to execute the process by using the detection of the change in the communication speed as a trigger.
Further, the detection unit 31 does not have to execute the process based on the reference information 91. In this case, the reference information 91 does not have to be stored in the non-volatile memory 19.
Further, the detection unit 31 may acquire the reference information 91 from an external server device or the like.
Further, the reception unit 33 does not have to accept the communication direction of the serial communication, the type of the error detection code given to the communication data of the serial communication for each communication direction, and the threshold value.

10 Logic analyzer, 13 Input module, 31 Detection unit (processing circuit), 33 Reception unit, 41 External interface, 91 Reference information (first reference information, second reference information).

Claims (8)

An input module that inputs communication data for serial communication whose communication speed is changed during communication,
Based on at least one of detecting a speed switching command for switching the communication speed used in the serial communication from the communication data of the serial communication and the pulse width time of one pulse included in the pulse signal of the serial communication. The detection unit that detects the change in the communication speed of the serial communication,
Logic analyzer equipped with. The detection unit
The logic analyzer according to claim 1, which analyzes the communication data of the serial communication input via the input module. Equipped with an external interface capable of communicating multiple signals
The detection unit
2. Of the plurality of signals, one signal is used to output the communication data of the serial communication of the analysis result, and the other signal is used to output the information of the communication speed of the serial communication of the detection result. Logic analyzer described in. The detection unit
The logic analyzer according to any one of claims 1 to 3, wherein the process is executed with the detection of a change in the communication speed of the serial communication as a trigger. It has a first reference information in which the first time is associated with the assumed data which is the data to be detected after the lapse of the first time.
The detection unit
The speed switching command is detected from the communication data of the serial communication, and the speed switching command is detected.
Based on the first reference information, after the first time has elapsed from the detection of the speed switching command, an abnormality is detected according to the fact that the assumed data cannot be detected from the communication data of the serial communication. The logic analyzer according to any one of items 1 to 4. A reception unit that can accept the communication direction of the serial communication, the type of the error detection code given to the communication data of the serial communication for each communication direction, and the threshold value for determining the number of detections of an error detected by the error detection code. With
The detection unit
Claims 1 to 1, wherein in the communication data of the serial communication corresponding to the communication direction received by the reception unit, an error is detected according to the number of times of detection of the error detection code by the error detection code. Item 5. The logic analyzer according to any one of Item 5. It has a second reference information in which the communication command used for the serial communication and the timeout time of the communication command are associated with each other.
The detection unit
The communication command is detected from the communication data of the serial communication,
Based on the second reference information, the timeout time associated with the detected communication command is set.
The invention according to any one of claims 1 to 6, wherein an abnormality is detected according to the fact that a response to the detected communication command cannot be detected between the time when the communication command is detected and the time when the timeout time elapses. Logic analyzer. A driver circuit that inputs communication data of other communication standards other than RS-232C standard and RS-485 standard and executes signal level conversion of the communication data of the other communication standards, and
With an external interface
The communication data of at least one of the RS-232C standard and the RS-485 standard is processed, and the signal level conversion is executed by the driver circuit. The communication data of the other communication standard is transmitted from the external interface. The processing circuit to output and
Logic analyzer equipped with.

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