JP2017030078A - Portable operation device and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily confirm a communication channel which is not used in an existing robot control system.SOLUTION: A teach pendant control section of a wireless teach pendant detects an identification signal (radio wave) transmitted by an existing wireless access point which is already installed. The teach pendant control section confirms which of communication channels is used to transmit the identification number and determines the communication channel as a channel being used. The teach pendant control section confirms a signal-to-noise ratio of the detected identification signal. The teach pendant control section excludes the channel being used from recommended channels and excludes communication channels in a prescribed frequency range according to the signal-to-noise ratio from the recommended channels.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a portable operating device and a program.

  In the robot control system disclosed in Patent Document 1, information is transmitted and received between a robot control device that controls the robot and a portable operation device that operates the robot by wireless communication according to the wireless LAN standard (IEEE.801.11 standard). In the wireless LAN standard, a plurality of communication channels are prepared, and a wireless communication connection is established between the robot control system and the portable operation device through any one communication channel.

JP 2008-80474 A

  By the way, for example, a new robot control system may be installed in a factory where the robot control system is installed. In this case, when a communication channel is set for a newly installed robot control system, it is necessary to set a communication channel different from the communication channel set for the existing robot control system. However, it is troublesome and troublesome to confirm which communication channel is set in the existing robot control system.

  The present invention has been made in view of the above points, and an object thereof is to enable easy confirmation of communication channels that are not used in an existing robot control system.

  In order to achieve the above object, the present invention provides a portable operation device capable of transmitting and receiving information to and from a robot control device that controls a robot by wireless communication. The wireless communication unit that receives radio communication radio waves transmitted by a device and the communication channels of radio waves of other devices received by the radio communication unit are used channels, and the plurality of communications that the radio communication unit can perform radio communication with It is characterized by determining a communication channel from which at least the in-use channel is excluded from the channels as a recommended channel that can be used, and outputting channel information related to the recommended channel.

  The present invention also relates to a portable operation including a wireless communication unit capable of wireless communication through a plurality of communication channels, and a control unit that controls a wireless communication process between the robot control device that controls the robot and the wireless communication unit. In a program for operating a device, the wireless communication unit is caused to execute a reception process for receiving a radio communication radio wave transmitted by another device, and the control unit is configured to receive a radio wave of the other device received by the radio communication unit. Judgment processing for determining a communication channel as a recommended channel that can be used as a communication channel, and a communication channel excluding at least the busy channel from the plurality of communication channels in which the wireless communication unit can perform wireless communication, and the recommendation And an output process for outputting channel information relating to the channel.

  According to the present invention, a communication channel that is not used in an existing robot control system can be easily confirmed.

Schematic of a robot control system. A block diagram of a wireless teach pendant. The flowchart of a communication channel search process. Explanatory drawing explaining the effect | action of a communication channel search process. The figure which shows the example of the image based on recommended channel image data and channel use condition image data.

(Robot control system configuration)
An embodiment of the portable operating device of the present invention will be described. First, an outline of a robot control system to which a wireless teach pendant TP as a portable operation device is applied will be described.

  As shown in FIG. 1, the robot control device RC of the robot control system has a control device main body CM that controls the operation of the robot R and the power supply to the robot R. The control device main body CM incorporates a computer, various modules, and the like. A wireless access point AP is fixed to the outer surface of the casing of the control device main body CM. The wireless access point AP is connected to the control device main body CM by wire, and inputs and outputs signals with the control device main body CM by wired communication. The wireless access point AP periodically transmits an identification signal (SSID: Service Set Identifier) that can distinguish itself from other wireless access points AP without designating a destination. The robot R is a multi-joint type welding robot having a plurality of arms driven by, for example, a servo motor and having a welding torch mounted on the arm at the tip. In the robot R, the operation of the arm or the like is controlled by a signal from the control device body CM.

  As shown in FIG. 1, the robot control system includes a wireless teach pendant TP for operating the robot R and inputting teaching contents to the robot R. The wireless teach pendant TP transmits and receives information to and from the wireless access point AP of the robot controller RC by wireless communication.

Next, the electrical configuration of the wireless teach pendant TP will be described.
As shown in FIG. 2, the teach pendant controller TP responsible for input processing and radio communication processing is provided in the wireless teach pendant TP. The teach pendant control unit 11 includes a central processing unit 11a (CPU) that executes various programs, a volatile RAM 11b that temporarily stores data when the program is executed, and a nonvolatile that stores programs necessary for processing. It is comprised as a computer which has the storage part 11c of sex. The storage unit 11c of the teach pendant control unit 11 stores a program for executing a communication channel search process, which will be described later, and setting values used in the communication channel search process.

  As shown in FIG. 2, the wireless teach pendant TP is provided with a display 12 for displaying various information. The display 12 displays an image based on the image data output from the teach pendant control unit 11. Examples of the image displayed on the display 12 include an image of information related to the robot R such as the current status of the robot R and teaching contents for the robot R, and an image of information related to recommended channels obtained by a communication channel search process described later. Etc. The wireless teach pendant TP is provided with a keyboard 13 for inputting information. The keyboard 13 is, for example, an arrow key for moving a selection position (cursor position) displayed on the display 12, a character key for inputting character / numeric information, a numeric keypad, and the like.

  As shown in FIG. 2, the wireless teach pendant TP has an enable switch 14 for permitting power supply to the robot R and an emergency stop switch 15 for forcibly stopping the robot R to which power is supplied. Is provided. The wireless teach pendant TP is provided with a channel search switch 16 for causing the teach pendant control unit 11 to execute a communication channel search process. When the channel search switch 16 is operated, the teach pendant control unit 11 of the wireless teach pendant TP starts a communication channel search process. The wireless teach pendant TP is provided with a timer 17 for measuring time. The timer 17 counts up and clears the count value based on a command from the teach pendant control unit 11.

  As shown in FIG. 2, the wireless teach pendant TP is provided with a wireless LAN interface 18 as a wireless communication unit for wireless communication with the wireless access point AP of the robot controller RC. The wireless LAN interface 18 incorporates an antenna for transmitting and receiving radio waves and a communication module for controlling wireless communication using the antenna. The wireless LAN interface 18 can perform wireless communication in a frequency band of 5 GHz in the IEEE 802.11 standard. The frequency band of this 5 GHz band includes 36 ch (5180 MHz), 40 ch (5200 MHz), 44 ch (5220 MHz), 48 ch (5240 MHz), 52 ch (5260 MHz), 56 ch (5280 MHz), 60 ch (5300 MHz), 64 ch (5320 MHz), 100 ch. (5500 MHz), 104 ch (5520 MHz), 108 ch (5540 MHz), 112 ch (5560 MHz), 116 ch (5580 MHz), 120 ch (5600 MHz), 124 ch (5620 MHz), 128 ch (5640 MHz), 132 ch (5660 MHz), 136 ch (5680 MHz), 140 ch A total of 19 communication channels are prepared (5700 MHz).

(Communication channel search processing)
Next, communication channel search processing executed by the wireless teach pendant TP will be described with reference to FIG.

  For example, when a new robot control system is to be additionally installed in a factory where another robot control system has already been installed, the wireless teach pendant TP is placed at a candidate position where the wireless access point AP of the robot controller RC is to be installed. Place. At this time, it is assumed that the wireless access point AP of the robot control system to be newly installed is turned off and does not transmit radio waves. Then, when the operator operates the channel search switch 16 in the wireless teach pendant TP, the teach pendant control unit 11 of the wireless teach pendant TP starts a communication channel search process. When the communication channel search process is started, the teach pendant control unit 11 of the wireless teach pendant TP clears the count value of the timer 17 and then increments the count value. Thereafter, the processing of the wireless teach pendant TP proceeds to step S1.

  As shown in FIG. 3, in step S1, the teach pendant control unit 11 searches for radio waves of an existing wireless access point AP that has already been installed. Specifically, the wireless access point AP periodically transmits an identification signal for distinguishing itself from other wireless access points AP without specifying a destination. Then, the wireless LAN interface 18 of the wireless teach pendant TP receives the identification signal transmitted by the wireless access point AP. The teach pendant control unit 11 searches the radio access point AP of the existing robot control system for radio waves by detecting whether the identification signal is received by the wireless LAN interface 18. Note that the wireless LAN interface 18 of the wireless teach pendant TP receives the identification signal transmitted by the wireless access point AP is a reception process of receiving radio communication radio waves transmitted by other devices. Thereafter, the processing of the wireless teach pendant TP proceeds to step S2.

  In step S2, the teach pendant control unit 11 determines whether or not a certain time has elapsed since the communication channel search process was started. Specifically, the teach pendant control unit 11 determines that a certain period of time has elapsed when the count value of the timer 17 is equal to or greater than a predetermined value, and when it is less than the predetermined value, the certain period of time has yet to elapse. Judge that there is no. If the predetermined time has not elapsed (NO in step S2), the processing of the wireless teach pendant TP returns to step S1 and continues to search for an identification signal transmitted by the wireless access point AP. When the predetermined time has elapsed (YES in step S2), the processing of the wireless teach pendant TP proceeds to step S3.

  In step S3, the teach pendant control unit 11 determines whether or not an identification signal (radio wave) transmitted by the wireless access point AP of the existing robot control system has been detected. If none of the identification signals transmitted by the wireless access point AP can be detected (NO in step S3), the teach pendant control unit 11 creates image data indicating that fact and outputs the image data to the display 12. It is displayed on the display 12. Thereafter, the processing of the wireless teach pendant TP ends. If one or more identification signals transmitted by the wireless access point AP can be detected (YES in step S3), the processing of the wireless teach pendant TP proceeds to step S4.

  In step S4, the teach pendant control unit 11 sets the total number of detected identification signals of each wireless access point AP to N, and assigns a detection number [i] to each identification signal. Specifically, for example, when two identification signals are detected in step S1, “N = 2”, and the detection number [1] and the detection number for the identification signal of the wireless access point AP in the detected order. [2] is attached. Thereafter, the processing of the wireless teach pendant TP proceeds to step S5.

  In step S5, the teach pendant control unit 11 checks which communication channel is used to transmit the detected identification signal, and determines that the communication channel is a busy channel. Also, the signal-to-noise ratio of the detected identification signal is confirmed. Further, the teach pendant control unit 11 stores the confirmed communication channel (in-use channel) and signal-to-noise ratio in the storage unit 11c in association with the corresponding identification signal. This process is performed for the identification signals of all detection numbers. In the following description, the communication channel being used in the identification signal of detection number [i] is described as communication channel [i], and the signal-to-noise ratio of the identification signal of detection number [i] is described as SNR [i]. To do. After storing the communication channel [i] and SNR [i] of each identification signal, the processing of the wireless teach pendant TP proceeds to step S6.

  In step S6, the teach pendant control unit 11 sets “i = 1”. Then, in step S7, the teach pendant control unit 11 refers to the communication channel [1] stored in the storage unit 11c in step S5, and the 19 communications in which the wireless LAN interface 18 of the wireless teach pendant TP can communicate. By excluding the communication channel [1] from the channels, the communication channel [1] is excluded from the recommended channels. In step S8, the communication channel having the frequency ± 20 MHz of the communication channel [1] is excluded from the 19 communication channels that can be communicated with by the wireless LAN interface 18, thereby excluding the communication channel from the recommended channel. Thereafter, the processing of the wireless teach pendant TP proceeds to step S9.

  In step S9, the teach pendant control unit 11 refers to the SNR [1] stored in the storage unit 11c in step S5, and determines whether SNR [1] is greater than 50. If SNR [1] is not greater than 50, that is, SNR [1] is 50 or less (NO in step S9), the process of wireless teach pendant TP proceeds to step S15. On the other hand, when SNR [1] is larger than 50 (YES in step S9), the process of the wireless teach pendant TP proceeds to step S10.

  In step S10, the teach pendant control unit 11 excludes the communication channel having the frequency ± 40 MHz of the communication channel [1] from the 19 communication channels with which the wireless LAN interface 18 can communicate, thereby setting the communication channel as the recommended channel. Exclude from Thereafter, the processing of the wireless teach pendant TP proceeds to step S11.

  In step S11, the teach pendant control unit 11 refers to the SNR [1] stored in the storage unit 11c in step S5 and determines whether SNR [1] is greater than 60. When SNR [1] is not greater than 60, that is, SNR [1] is 60 or less (NO in step S11), the processing of the wireless teach pendant TP proceeds to step S15. On the other hand, when SNR [1] is larger than 60 (YES in step S11), the process of the wireless teach pendant TP proceeds to step S12.

  In step S12, the teach pendant control unit 11 selects the communication channel [1] with a frequency of ± 60 MHz and the communication channel [1] with a frequency of ± 80 MHz from 19 communication channels with which the wireless LAN interface 18 can communicate. By excluding these communication channels, those communication channels are excluded from the recommended channels. Thereafter, the processing of the wireless teach pendant TP proceeds to step S13.

  In step S13, the teach pendant control unit 11 refers to the SNR [1] stored in the storage unit 11c in step S5 and determines whether SNR [1] is greater than 70. When SNR [1] is not greater than 70, that is, SNR [1] is 70 or less (NO in step S13), the process of the wireless teach pendant TP proceeds to step S15. On the other hand, when SNR [1] is larger than 70 (YES in step S13), the process of the wireless teach pendant TP proceeds to step S14.

  In step S14, the teach pendant control unit 11 selects the communication channel [1] with a frequency of ± 100 MHz and the communication channel [1] with a frequency of ± 120 MHz from the 19 communication channels with which the wireless LAN interface 18 can communicate. By excluding these communication channels, those communication channels are excluded from the recommended channels. Thereafter, the processing of the wireless teach pendant TP proceeds to step S15. Further, as described above, also when the determinations in step S9, step S11, and step S13 are negative (NO), the processing of the wireless teach pendant TP proceeds to step S15.

  In step S15, it is determined whether or not the numerical value set as [i] is smaller than [N], which is the total number of detected identification signals. For example, when the total number of detected identification signals is [2], since the numerical value set as [i] here is [1], it is determined that [i] is smaller than [N]. In this case (YES in step S15), 1 is added to the numerical value of [1] to obtain [i] = [2]. Thereafter, the processing of the wireless teach pendant TP returns to step S7, and the communication signal [2] and SNR [2] stored in step S5 are referred to for the identification signal of the detection number [2] in steps S7 to S15. Processing is performed. The processes in steps S7 to S15 are repeatedly executed while adding the numerical value of [i] by one until the numerical value set as [i] matches [N] which is the total number of detected identification signals. The Therefore, a series of processing is performed on all detected identification signals.

  In the process of step S15 of the wireless teach pendant TP, when the numerical value set as [i] is not smaller than [N] that is the total number of identification signals detected, that is, the numerical value set as [i] When it matches [N] that is the total number of detected identification signals (NO in step S15), the teach pendant control unit 11 of the wireless teach pendant TP stores the communication channels excluded from the recommended channels in the series of processes as excluded channels. It memorize | stores in the part 11c. Further, the teach pendant control unit 11 stores the communication channels that are not excluded in the storage unit 11c as recommended channels. Thereafter, the communication channel search process of the wireless teach pendant TP ends.

  As described above, in this embodiment, the busy channel used in the received identification signal is excluded from the recommended channels. Further, the frequency range of the communication channel to be excluded is determined according to the signal-to-noise ratio of the received identification signal, and communication channels within a predetermined frequency range including the busy channel are excluded.

  Of the communication channel search processes described above, the processes in steps S4 to S16 are determination processes for determining recommended channels by excluding excluded channels from a total of 19 communication channels with which the wireless LAN interface 18 can communicate. is there. The teach pendant control unit 11 that executes the determination process is a determination unit that determines a recommended channel.

(Recommended channel display processing)
Next, the recommended channel display process executed by the wireless teach pendant TP will be described.

  When the above-described communication channel search process ends, the wireless teach pendant TP continues to execute a recommended channel display process. In the recommended channel display process, first, recommended channel image data is generated as channel information related to the recommended channel stored in the storage unit 11 c of the teach pendant control unit 11. Specifically, for example, as shown in FIG. 5, the recommended channels stored in the storage unit 11c are displayed in black characters, the excluded channels stored in the storage unit 11c are displayed in white characters, and the recommended channels are displayed. Data for displaying an image that can be distinguished from the exclusion channel is generated as recommended channel image data.

  In addition, the teach pendant control unit 11 generates a channel use state image in which the identification signal stored in the storage unit 11c in step S5 in the communication channel search process, the communication channel corresponding to the identification signal, and the signal noise ratio can be confirmed. Specifically, for example, as shown in FIG. 5, image data in which communication channels, identification signals (SSIDs), signal-to-noise ratios, and the like are listed is generated as channel usage status image data. Then, the teach pendant control unit 11 executes an output process for outputting the generated recommended channel image data and channel usage status image data to the display 12. The display 12 displays the image shown in FIG. 5 based on the input recommended channel image data and channel usage status image data. Thus, the operator can confirm the communication channel used in the existing robot control system by viewing the image displayed on the display 12 of the wireless teach pendant TP, and at the place where the communication channel search process is performed. It is possible to confirm a communication channel that is unlikely to cause interference.

(Operation of wireless teach pendant)
Next, a specific example in which the wireless teach pendant TP performs a communication channel search process and a recommended channel display process will be described together with its operation.

  As shown in FIG. 4, there are a robot control system A for operating the robot Ra and a robot control system B for operating the robot Rb as existing robot control systems. In the wireless access point APa of the robot control system A, “Robot01” is set as an identification signal (SSID), and wireless communication is performed with the wireless teach pendant TPa through the communication channel “100ch”. In addition, “Robot02” is set as an identification signal (SSID) in the wireless access point APb of the robot control system B, and wireless communication is performed with the wireless teach pendant TPb through the communication channel “136ch”. .

  In the above situation, it is assumed that a new robot control system is to be installed at a position relatively far from the wireless access point APa of the robot control system A and relatively close to the wireless access point APb of the robot control system B. . In this case, as shown in FIG. 4, first, the wireless teach pendant TP is disposed at the installation candidate position of the wireless access point AP of the new robot control system. At this position, the wireless teach pendant TP is caused to execute the communication channel search process described above. Then, in the wireless teach pendant TP, the identification signal “Robot01” transmitted by the wireless access point APa is detected, “100ch” is detected as the communication channel, and “30” is detected as the signal to noise ratio. Also, the identification signal “Robot02” transmitted by the wireless access point APb is detected, “136 ch” is detected as the communication channel, and “55” is detected as the signal to noise ratio.

  Here, since the communication channel of the identification signal “Robot01” is “100ch”, “100ch” is excluded from the recommended channels by the process of step S7 shown in FIG. Further, “104 ch” using the frequency of “100 ch” + the frequency of 20 MHz is also excluded from the recommended channels by the process of step S <b> 8 shown in FIG. 3. In the wireless LAN standard, a communication channel using a frequency of “100 ch” −20 MHz is not prepared, and therefore, a process of excluding a communication channel having a frequency of “100 ch” −20 MHz is not performed. Since the signal-to-noise ratio “30” of the identification signal “Robot01” is 50 or less, a communication channel using a frequency of “100 ch” ± 40 to 120 MHz is not excluded.

  On the other hand, since the communication channel of the identification signal “Robot02” is “136ch”, “136ch” is excluded from the recommended channels by the process of step S7 shown in FIG. Also, “132ch” and “140ch” using the frequency of “136 ch” ± 20 MHz are also excluded from the recommended channels by the process of step S8 shown in FIG. Furthermore, since the signal-to-noise ratio “55” of the identification signal “Robot02” is larger than 50, “128ch” using the frequency of “136ch” −40 MHz is excluded by the process of step S10 shown in FIG. In the wireless LAN standard, a communication channel that uses a frequency of “136 ch” +40 MHz is not prepared, and therefore, a process that excludes a communication channel that uses a frequency of “136 ch” + frequency of 40 MHz is not performed. Since the signal-to-noise ratio “55” of the identification signal “Robot02” is 60 or less, a communication channel using a frequency of “136 ch” of ± 60 to 120 MHz is not excluded.

  When the communication channel to be excluded from the recommended channels is determined by the above processing, as shown in FIG. 5, the display 12 of the wireless teach pendant TP has “100 ch”, “ The communication channels “104ch”, “128ch”, “132ch”, “136ch”, and “140ch” are displayed in white letters. The other 13 communication channels are displayed in black characters as recommended channels. In addition, the detected identification signals “Robot01” and “Robot02”, and their communication channels and signal-to-noise ratios are displayed on the display 12 of the wireless teach pendant TP in the form of a list. Then, if a wireless access point AP in a new robot control system is arranged at a position where a series of communication channel search processing is performed by the wireless teach pendant TP, and any one of the recommended channels is set, the existing A communication channel that is not used in the robot control system A and the robot control system B and that is unlikely to cause interference can be set in the newly installed robot control system.

(Characteristics and effects of wireless teach pendant)
The above robot control system has the following features and effects.
(1) In the above embodiment, the teach pendant control unit 11 of the wireless teach pendant TP determines a recommended channel except for the communication channel used in the identification signal received by the wireless LAN interface 18, and recommends the recommended channel. The channel image data is output to the display 12. By viewing an image based on the recommended channel image data, the operator can easily confirm a communication channel that is not used in the existing robot control system.

  (2) In the above embodiment, the teach pendant control unit 11 determines that the communication channel excluding the communication channel within a certain frequency including the communication channel used in the identification signal received by the wireless LAN interface 18 is the recommended channel. . That is, the frequency of the recommended channel is more than a certain frequency away from the frequency of the already used communication channel. Therefore, it is possible to determine a communication channel that is unlikely to generate interference due to the close proximity of frequencies as a recommended channel.

  (3) The magnitude of the signal-to-noise ratio of the received identification signal reflects the distance from the wireless access point AP that transmitted the identification signal, and reflects the magnitude of the influence of radio waves of the wireless access point AP It can be said that. In this regard, in the above embodiment, the larger the signal-to-noise ratio of the identification signal, the larger the frequency range of the communication channel to be excluded, and the communication channel with a further frequency is determined as the recommended channel. Therefore, an appropriate communication channel reflecting the magnitude of the influence of radio waves at the wireless access point AP can be determined as a recommended channel.

  (4) In the above embodiment, not only the recommended channel image data related to the recommended channel, but also the channel usage image data that can confirm the received identification signal, the communication channel corresponding to the identification signal, and the signal-to-noise ratio is generated and displayed. 12 is displayed. Therefore, it is possible to confirm which robot control system's wireless access point AP is within the communication range of the communication channel search processing performed by the wireless teach pendant TP, and to determine the distance to the wireless access point AP as a signal-to-noise ratio. Can be guessed based on.

  (5) A series of communication channel search processes and the like can be executed in the wireless teach pendant TP. Therefore, even if the robot T or the robot controller RC is not carried to the installation candidate position, the communication channel search process or the like can be executed as long as the wireless teach pendant TP that is relatively small and excellent in portability is carried.

(Example of change)
Each of the above embodiments may be modified as follows. Moreover, you may apply combining each modification example suitably.

  In the robot control system to which the wireless teach pendant TP of the above embodiment is applied, the robot R is not limited to an articulated welding robot, and may be a transfer robot or a work robot. Also, the configuration of the robot controller RC can be changed as appropriate as long as wireless communication with the wireless teach pendant TP is possible in any of the plurality of notification channels. For example, a teach pendant may be connected to the control device main body CM of the robot control device RC in a wired manner separately from the wireless teach pendant TP.

  In the above embodiment, the wireless access point AP is fixed to the outer surface of the casing of the control device main body CM. . For example, it may be installed near the robot R, or may be fixed to a safety fence surrounding the robot R.

  The wireless teach pendant TP can be used with any terminal as long as it can wirelessly communicate with a plurality of communication channels and can receive radio communication radio waves from other devices. For example, a smart phone, a tablet terminal, and a PDA terminal are mentioned.

  The channel search switch 16 can be omitted from the wireless teach pendant TP. When the channel search switch 16 is omitted, for example, an icon or a character string for executing a communication channel search process is displayed on the display 12, and the icon or character string is displayed by operating the keyboard 13. When it is selected, the communication channel search process may be executed.

  The method and frequency of wireless communication between the wireless teach pendant TP and the wireless access point AP are not limited to the wireless LAN standard. A technique relating to the wireless teach pendant TP of the above embodiment can be applied as long as a plurality of communication channels are prepared and the communication standard allows wireless communication in any of the plurality of communication channels.

  In the above embodiment, the wireless access point AP is searched depending on whether or not the identification signal transmitted by the wireless access point AP has been received. However, the wireless access point AP is searched by receiving radio waves other than the identification signal. You may make it do. For example, the wireless access point AP may be searched based on whether or not the radio access point AP has received a radio wave (signal) transmitted to another device.

  The relationship between the signal noise ratio and the frequency range of the communication channel to be excluded is not limited to the example in the above embodiment. What is necessary is just to set suitably in consideration of the kind, frequency band, sensitivity, output, etc. of the wireless communication standard in wireless access point AP and wireless teach pendant TP.

  -The frequency range of communication channels to be excluded may be unchanged. That is, regardless of the signal-to-noise ratio of the received identification signal, communication channels having a certain range of frequencies including the communication channel used in the received identification signal may be excluded. In this case, it is not always necessary to confirm the signal-to-noise ratio of the received identification signal.

  ・ If at least the communication channels used in the received identification signal are excluded, the communication channels that are not used in the existing robot control system are notified to the operator without excluding other communication channels. Can do. For example, in the wireless LAN standard using the 5 GHz band as in the above embodiment, the frequencies do not overlap in each communication channel. For this reason, if different communication channels are set in a plurality of robot control systems, the possibility of interference and the like is not high. In this case, if at least communication channels used in the existing robot control system are excluded and other communication channels are determined as recommended channels, communication channels that are unlikely to cause interference can be determined as recommended channels.

  -In the said embodiment, if it is a parameter reflecting the intensity | strength of the radio wave of an identification signal, it is not necessary to use a signal noise ratio. For example, depending on the location in the factory, it is possible that noise with a suitable intensity is generated, so it may be better to adopt signal intensity rather than signal-to-noise ratio.

  In the above embodiment, the excluded channel is stored in the storage unit 11c of the teach pendant control unit 11 after the series of communication channel search processes is completed. For example, in step S7, step S8, step S10, and step S12 Each time a communication channel is excluded, the excluded channel may be stored in the storage unit 11c.

  In the above embodiment, the teach pendant control unit 11 of the wireless teach pendant TP outputs the recommended channel image data to the display 12, but outputs the recommended channel image data to another display device instead of or in addition to the display 12. You may make it do. For example, if a teach pendant is connected to the robot controller RC in addition to the wireless teach pendant TP, recommended channel image data may be output to the teach pendant. Further, if the display device is provided in the control device main body CM of the robot control device RC, the recommended channel image data may be output to the display device of the control device main body CM.

  In the above embodiment, the generation and output of channel usage status image data can be omitted. In addition, image data indicating other information related to wireless communication may be output together with recommended channel image data and channel usage status image data.

  The mode of the image based on the recommended channel image data is not limited to the mode shown in FIG. For example, an icon indicating whether the communication channel can be used or not used in the robot control system to be newly installed may be displayed near the display of each communication channel. Further, only the recommended channels among the communication channels may be displayed and the excluded channels may not be displayed. On the contrary, only the excluded channel may be displayed and only the recommended channel may be displayed. Even when only the excluded channel is displayed, the operator can indirectly understand that the communication channel that is not displayed is the recommended channel. Therefore, even if the recommended image data in this case does not directly include data for specifying the recommended channel, it can be said that the channel information is related to the recommended channel.

  In the above embodiment, the recommended channel image data is output to the display 12 as the channel information related to the recommended channel, and the image is displayed. However, the channel information and the manner of notification thereof are not limited thereto. For example, an indicator lamp corresponding to a plurality of communication channels may be provided in the wireless teach pendant TP, and only the indicator lamp corresponding to the recommended channel may be turned on. In this case, a signal for lighting and blinking each indicator lamp corresponds to channel information. Further, a speaker may be provided in the wireless teach pendant TP, and a sound for reading out a recommended channel may be emitted from the speaker. In this case, audio data indicating the audio corresponds to channel information.

  3) Color-code the used channels excluded in step S7 in FIG. 3 and the communication channels excluded in step S10, step S12, and step S14 to generate image data that can be distinguished from each other. Also good.

  In the above embodiment, the communication channel that is least likely to cause interference among the recommended channels may be determined as the optimum channel, and the optimum channel information regarding the optimum channel may be output. For example, a recommended channel having a frequency farthest from the frequency of the communication channel used in the identification signal among the recommended channels may be determined as the optimum channel. Further, among the recommended channels, a recommended channel having a frequency that is a predetermined frequency or more away from the frequency of the communication channel used in the identification signal may be determined as the optimum channel. When the optimum channel is determined, the optimum channel and other recommended channels can be displayed in a distinguishable manner by color-coding the optimum channel and other recommended channels in the image based on the recommended channel image data. In this case, the recommended channel image data also corresponds to optimum channel information.

  For example, if a display or the like is provided in the control device main body CM or the wireless access point AP of the robot control device RC and information on the recommended channel can be displayed, the communication channel search process in the above embodiment and the recommended channel thereafter The robot controller RC may execute the display process. Even in this case, if a cable or the like connecting the robot R and the robot controller RC is removed, the communication channel in use in the existing robot control system can be confirmed without bringing the robot R to the installation candidate position.

The following technical idea can be derived from the above-described embodiment and modified examples.
The determination unit is more than a predetermined frequency away from the communication channel farthest from the frequency of the in-use channel or the frequency of the in-use channel from among the plurality of communication channels with which the radio communication unit can perform radio communication. The frequency communication channel is determined to be the optimum channel, and the output unit outputs optimum channel information related to the optimum channel.

  R ... Robot, RC ... Robot controller, CM ... Control device main body, AP ... Wireless access point, TP ... Wireless teach pendant, 11 ... Teach pendant controller, 12 ... Display, 13 ... Keyboard, 14 ... Enable switch, 15 ... Emergency stop switch, 16 ... channel search switch, 17 ... timer, 18 ... wireless LAN interface.

Claims (4)

In a portable operation device capable of transmitting and receiving information to and from a robot control device that controls a robot,
A wireless communication unit capable of wireless communication through a plurality of communication channels and receiving radio communication radio waves transmitted by other devices;
The communication channel of the radio wave of the other device received by the wireless communication unit is used as a used channel, and at least the used channel is excluded from the plurality of communication channels capable of wireless communication by the wireless communication unit. A portable operation device comprising: a determination unit that determines a possible recommended channel and outputs channel information related to the recommended channel. The determination unit determines that a communication channel excluding a communication channel within a certain frequency including the in-use channel from the plurality of communication channels in which the wireless communication unit can perform wireless communication is determined as the recommended channel. The portable operation device according to claim 1. The portable operation device according to claim 2, wherein the determination unit increases the range of the constant frequency as the radio wave intensity of the other device received by the wireless communication unit increases. In a program for operating a portable operation device including a wireless communication unit capable of wireless communication through a plurality of communication channels, and a control unit that controls wireless communication processing between the robot control device that controls the robot and the wireless communication unit ,
In the wireless communication unit,
Execute reception processing to receive radio communication radio waves transmitted by other devices,
In the control unit,
The communication channel of the radio wave of the other device received by the wireless communication unit is used as a used channel, and at least the used channel is excluded from the plurality of communication channels capable of wireless communication by the wireless communication unit. A program for executing a determination process for determining a possible recommended channel and an output process for outputting channel information related to the recommended channel.