JP2018031618A - Surveying instrument communication processing system and defect processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a surveying instrument communication processing system and defect processing method, which collect surveying environment information and make the surveying environment information reflect on defect processing.SOLUTION: A communication processing system according to the present invention, comprises: a telescope (1c) that is provided with a surveying unit (13) capable of aiming at a target and surveying the target, and a camera (12) for taking an aiming image; a surveying instrument (1) that is provided with a display unit (18) serving as an input interface for instructing the surveying unit to survey, a control unit (15) for controlling the surveying unit, the camera, and the display unit, a storage unit (16) for recording information acquired by the control unit, and a communication unit (17) for enabling communication of the control unit with an external network; a server (3) capable of storing the information recorded in the storage unit via the external network; and a remote terminal (2) that is accessible to the information stored in the server. The surveying instrument is configured to transmit surveying data obtained by the surveying unit and images taken by the camera to the remote terminal via the server.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a communication processing system and a failure processing method for a surveying instrument.

  The surveying instrument (total station) irradiates a target with a distance measuring light placed at a measurement point, and receives the reflected light to perform distance measurement. However, there may be a problem that this function is not performed or the measured value is less than the accuracy guaranteed.

  In the communication processing system of Patent Document 1, the number of distance measurement, the number of program activations, the error code, the date of occurrence, the time of occurrence, the distance measurement value, the angle measurement value, the substrate temperature, the humidity, the output value of each board, Record memory dump, maintenance history, license period, usage authority confirmation, program version information, and send these information to remote terminal. In the communication processing system of Patent Literature 2, the surveying instrument itself performs self-checking, troubleshooting, and creation of an inquiry table based on the recording of information including the above, and transmits these results to a remote terminal. Engineers at remote locations search for the cause of the trouble of the surveying instrument based on this information and try to solve it.

JP 2007-170978 A JP 2012-117874 A

  However, there are various causes of malfunctions, such as instrument parts defects, program setting errors, secular deviations in setting conditions, surveying environments, etc., or they are intricately intertwined, and it is difficult to identify them at present. is there. In the conventional communication processing system, there are many things that take information for grasping the usage state of the surveying instrument, but the recording of the usage state does not always lead to the elucidation of the cause, and the cause cannot be identified.

  In particular, the conventional information lacked information on the “surveying environment”, such as the fact that the weather was clear during surveying, construction vibrations, and obstacles were passing at the timing of distance measurement. If such a “surveying environment” can be known, the cause elucidation may be accelerated.

  An object of the present invention is to provide a communication processing system for a surveying instrument and a defect processing method that collect more information on “surveying environment” as a judgment material and reflect the collected information in the defect processing.

  In order to solve the above-described problems, a communication processing system for a surveying instrument according to an aspect of the present invention includes a surveying unit capable of collimating a target and a telescope including a camera that captures a collimated image, and measuring the surveying unit. A display unit that functions as an input interface for instructing, the surveying unit, the camera, and a control unit that controls the display unit, a storage unit that records information acquired by the control unit, and communication between the control unit and an external network A surveying instrument including a communication unit that enables communication, a server that can store information recorded in the storage unit via the external network, and a remote terminal that can access the information stored in the server. The surveying instrument transmits the measurement data obtained by the surveying unit and the image of the camera to the remote terminal via the server.

  The said aspect WHEREIN: It is also preferable that the said surveying instrument transmits the image of the said display part to the said remote terminal via the said server.

  In the above aspect, the surveying instrument further includes a microphone, the control unit records a voice signal of the microphone in the storage unit, and the surveying instrument further transmits the voice signal to the remote terminal via the server. It is also preferable.

  In the above aspect, preferably, the surveying instrument further includes a speaker, and the surveying instrument is capable of making a call with the remote terminal via the external network or a mobile phone line.

  Using the communication processing system of the above aspect, the measurement data at the time of occurrence of a malfunction, the image of the camera, the image of the display unit, the audio signal, or a combination thereof is acquired at the remote terminal, and the measurement data It is also preferable to determine an operating procedure or target error from the image on the display unit, check the camera image and / or the audio signal, and determine an environmental abnormality.

  According to the present invention, by collecting more information on the “surveying environment” as a judgment material, this can be reflected in the defect processing.

It is a block diagram of the communication processing system for surveying instruments which concerns on embodiment. It is a right perspective view of the surveying instrument used for the system of FIG. It is a flowchart of defect information acquisition. It is a trouble communication flowchart. It is a flowchart of defect judgment.

  Next, preferred embodiments of the present invention will be described with reference to the drawings.

(System configuration)
FIG. 1 is a block diagram of a communication processing system for a surveying instrument (hereinafter simply referred to as a system) according to an embodiment, and FIG. 2 is a right perspective view of the surveying instrument used in the system of FIG. In this system, the surveying instrument 1 and the remote terminal 2 are connected through an external network such as the Internet via a server 3 and a mobile phone line.

  The surveying instrument 1 is a total station. As shown in FIG. 1, the surveying instrument 1 functionally includes a first camera 11, a second camera 12, a surveying unit 13, a GPS 14, a CPU 15, a memory 16, a communication unit 17, a display unit 18, a microphone 19, and a speaker. 20, a horizontal rotation drive unit 21, and a vertical rotation drive unit 22. In appearance, as shown in FIG. 2, the base part 1a provided on the leveling device, the frame part 1b that rotates horizontally on the base part 1a, and the telescope that rotates vertically at the center of the frame part 1b. 1c.

  The telescope 1c includes a collimating optical system that collimates a target, a second camera 12 that acquires an image (including a moving image) in a collimating direction through the collimating optical system, and a field of view at a lower magnification than the second camera 12. It has the 1st camera 11 which acquires a wide image (a moving image is included). The first camera 11 and the second camera 12 output the captured image as a digital image signal. The camera may be only the second camera 12.

  The telescope 1c has a surveying unit 13 that shares optical elements with the collimating optical system. The surveying unit 13 includes a light emitting element, a distance measuring optical system, and a light receiving element, emits distance measuring light from the light emitting element, receives light reflected from the target by the light receiving element, and measures the target. Further, the surveying unit 13 measures the rotation angle of the rotary shaft driven by the horizontal rotation driving unit 21 and the vertical rotation driving unit 22 described later using an angle detector (not shown).

  The horizontal rotation drive unit 21 and the vertical rotation drive unit 22 are motors, and are controlled by the CPU 15 to rotate the rack 1b horizontally and rotate the telescope 1c vertically.

  The display unit 18 has a liquid crystal screen and can be input with an operation button or a touch panel. An image related to the survey application appears on the LCD screen, and the operator is guided to input the measurement conditions, target collimation, automatic collimation, and start / end of the measurement, and confirm the measurement result. can do. Note that images of the first camera 11 and the second camera 12 can also be displayed on the liquid crystal screen.

  The microphone 19 and the speaker 20 are accommodated in the rack part 1b. The microphone 19 collects the voice uttered by the worker and the sound around the surveying instrument 1, converts it into a voice signal, and outputs it. The speaker 20 outputs the other party's voice based on an instruction from the CPU 15. Note that the remote terminal 2 which is a call partner is also provided with a microphone and a speaker.

  The communication unit 17 enables communication with an external network, connects to the Internet using the Internet protocol (TCP / IP), and transmits information recorded in the memory 16. Also, information from the remote terminal 2 is received.

  The CPU 15 executes various processes based on various information input from the cameras 11 and 12, the surveying unit 13, the GPS 14, the driving units 21 and 22, the communication unit 17, the display unit 18, and the microphone 19. For example, a surveying application program is executed, and a screen according to the application is displayed on the display unit 18. Further, the driving units 21 and 22 and the surveying unit 13 are controlled to perform automatic target collimation, distance measurement and angle measurement, and measurement data (ranging angle measurement value, tilt, GPS, temperature, humidity, atmospheric pressure, date and time, Etc.). Also, the images of the cameras 11 and 12 being measured and the sound data of the microphone 19 being measured are acquired. In addition, information on the usage state of the surveying instrument 1, such as instrument internal status (usage time, battery, instrument adjustment data, software version), log (operation log, internal communication log, external communication log), and the like is acquired. The memory 16 stores various programs for the above processing. In addition, the memory 16 always records information acquired by the CPU 15.

  Next, a problem handling method using the communication processing system will be described.

(Defect information acquisition)
FIG. 3 is a flowchart of defect information acquisition. The surveying instrument 1 performs an image / audio recording task and a defect information recording task. In the image / sound recording task, information including the images of the cameras 11 and 12, the image of the display unit 18, and the sound of the microphone 19 is always recorded along with the date and time. When the recording capacity is insufficient, the oldest one may be deleted.

  When the surveying instrument 1 detects the occurrence of a failure due to an error detection, an excess of a reference value, an inquiry from the operator, etc., a failure information recording task is executed in step S101, and the information at the time of occurrence of the failure and immediately before is stored in memory. 16 is copied. When searching for the cause of a failure, information before the failure occurs is required. The copy range is preferably 3 to 5 minutes before the occurrence of the problem, considering the data amount and the storage capacity. However, this is only an example, and it is sufficient to secure a sufficient time to see the situation where the normal measurement is changed to the error measurement. Next, in step S102, the surveying instrument 1 transmits information on the occurrence of a failure to the server 3 periodically (for example, once a day). The server 3 accumulates information at the time of failure occurrence. In step S103, the remote terminal 2 requests the server 3 by designating information used for defect determination. In step S104, the server 3 transmits the requested information to the remote terminal 2.

(Defect report)
FIG. 4 is a trouble communication flowchart. In step S <b> 201, the surveying instrument 1 informs the operator from the display unit 18 or the speaker 20 when a problem occurs, and prompts to contact the remote terminal 2. In step S202, the worker makes a call from the call button on the display unit 18 to the engineer (remote terminal 2) via the mobile phone line. In step S <b> 203, the surveying instrument 1 transmits position information, model information, and a serial number to the server 3. The server 3 additionally transmits to the remote terminal 2 the registered worker name and surveying instrument model. In step S204, the surveying instrument 1 checks its own state and displays an error code or the like to the operator by displaying it on the display unit 18, for example. In step S205, the worker simply reports the failure state to the engineer. In step S206, the remote terminal 2 sends survey software to the surveying instrument 1 from the server 3, and acquires detailed information (software status, timing, statistical information, etc.) necessary for failure analysis from the surveying instrument 1. In step S <b> 207, the remote terminal 2 acquires past accumulated information from the server 3. In step S208, the technician simply reports the cause to the worker. In step S209, the engineer operates a countermeasure on the surveying instrument 1.

(Defect judgment)
FIG. 5 is a flowchart of defect determination. When starting the determination, the remote terminal 2 checks the type of error log in S301. If there is no error, the remote terminal 2 notifies the surveying instrument 1 that there is no error.

  If the error in S301 is a measurement error, the remote terminal 2 displays the measurement data and, if necessary, the image on the display unit 18 in S302. By checking not only the measurement data but also the image on the display unit 18, it is possible to verify whether the series of measurement operation procedures was correct. Also, it is possible to increase analysis information regarding software error / bug occurrence methods, operation methods, and procedures. If it is determined in S302 that the operation procedure is incorrect or the target is incorrect, the remote terminal 2 instructs the surveying instrument 1 on the measurement method as a measurement method error and prompts remeasurement.

  If the measurement data error is random in S302, the remote terminal 2 displays the images of the cameras 11 and 12 in S303. By confirming the image of the telescope, it is possible to increase analysis information called “surveying environment” such as shadow, sunlight reflection, bad weather, fog, presence of obstacles, presence of vibrations, and the like. If it is determined that there is an environmental error, the remote terminal 2 instructs the surveying instrument 1 to improve the surveying environment and prompts remeasurement. On the other hand, if no environmental abnormality is found in S303 and it is determined that the instrument is poorly adjusted, the remote terminal 2 notifies the surveying instrument 1 that it is necessary to readjust the instrument. The engineer creates an instrument adjustment program and sends it to the surveying instrument 1. The surveying instrument 1 receives this and updates the program.

  When the error of S301 is a hardware error, the remote terminal 2 displays on the surveying instrument 1 that the instrument is recovered and repaired. If the error in S301 is a communication error, in S304, the remote terminal 2 displays a communication log. If the error occurs when the power is turned on, the remote terminal 2 processes it as a hardware error. If it occurs during the measurement, it is determined as a software error, and the engineer creates an instrument adjustment program and transmits it to the surveying instrument 1. The surveying instrument 1 receives this and updates the program.

(effect)
According to this embodiment, since the image of the telescope 1c can be acquired by the remote terminal 2, the analysis information “surveying environment” can be increased, and the determination of the environmental error can be accelerated. In addition, if there is an image of the telescope 1c, it is possible to verify from the image whether the series of measurement work was correct. If the measurement is inappropriate, re-measurement and reconsideration / change of the measurement method can be performed. Judgment and instruction can be made from the two sides. Moreover, since it is obvious at a glance whether or not the telescope 1c is aimed at the target within the specified time by using the image, the motor drive error can be verified from a viewpoint different from the encoder value. Moreover, since the operator's face, appearance, clothes, eyeballs, fingerprints, etc. can be taken from the image, it is also a crime prevention measure. Further, the measurement position and measurement object obtained from the image can be compared with the current state map acquired by the GPS 14, and the habit and skill level of each worker can be known.

  According to the present embodiment, since the image of the display unit 18 can be acquired by the remote terminal 2, it is possible to confirm the occurrence of an error / bug regardless of the user report. In addition, since the operation information that is unclear or insufficient in the user report can be obtained objectively and quantitatively, the analysis information increases and accurate verification can be performed.

  According to the present embodiment, since the sound of the microphone 19 can be acquired by the remote terminal 2, the beep sound of the surveying instrument 1 can be used for verification. Further, the sound around the surveying instrument 1 can be used as analysis information of the surveying environment. In addition, if the microphone 19 is provided inside the main body of the surveying instrument 1, the motor sound of the drive units 21 and 22 can be acquired and used for verification of an error in the motor operation.

  According to the present embodiment, the microphone 19 and the speaker 20 are provided in the surveying instrument 1, so that the operator and the engineer can interact with each other as compared to the mail and SNS that are conventionally performed in the surveying instrument communication processing system. Get faster. Even if the operator does not explain, in step S203, S206, S207 in FIG. 4, the detailed information of the surveying instrument 1 can be immediately transmitted to the remote terminal 2 and the call can be performed in parallel with the data transfer. Therefore, it is possible to exchange more efficiently and quickly than using the operator's own mobile phone. In addition, since the call can be made hands-free, the burden on the operator can be reduced.

  Furthermore, according to the present embodiment, by centrally managing the defect information in the server 3, a defect in software that causes a defect only in a certain version, a problem that occurs only in connection with a certain data collector, or a lot that occurs only in a range of a certain serial number. It is possible to investigate rare problems such as hardware problems, problems that occur only in a certain temperature range, and how much has occurred in all instruments. For this reason, it is possible to take countermeasures against the occurrence of defects before reporting / complaints of defects from other machine operators and lots.

  As mentioned above, although preferable embodiment and the modification of this invention were described, this form and each modification can be combined based on the knowledge of those skilled in the art, and such a form is also contained in the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Surveyor 2 Remote terminal 3 Server 11 1st camera 12 2nd camera 13 Surveying part 14 GPS
15 CPU
16 Memory 17 Communication unit 18 Display unit 19 Microphone 20 Speaker 21 Horizontal rotation drive unit 22 Vertical rotation drive unit

Claims (5)

A surveying unit capable of collimating a target and a camera having a camera for capturing a collimated image, a display unit functioning as an input interface for instructing the surveying unit to perform measurement, the surveying unit, the camera, and a display unit A surveying instrument comprising: a control unit that controls; a storage unit that records information acquired by the control unit; and a communication unit that enables communication between the control unit and an external network;
A server capable of storing the information recorded in the storage unit via the external network;
A remote terminal capable of accessing information stored in the server,
The surveying instrument communication system for a surveying instrument, wherein the surveying instrument transmits the measurement data obtained by the surveying unit and the image of the camera to the remote terminal via the server.
The communication processing system for a surveying instrument according to claim 1, wherein the surveying instrument transmits the image on the display unit to the remote terminal via the server.
The surveying instrument further includes a microphone, the control unit records a voice signal of the microphone in the storage unit, and the surveying instrument further transmits the voice signal to the remote terminal via the server. A communication processing system for a surveying instrument according to claim 1 or 2.
4. The surveying instrument communication processing system according to claim 3, wherein the surveying instrument further includes a speaker, and the surveying instrument is capable of making a call with the remote terminal via the external network or a mobile phone line.
Using the communication processing system according to claim 4,
In the remote terminal, the measurement data at the time of occurrence of trouble, the image of the camera, the image of the display unit, the audio signal, or a combination thereof is acquired, and an operation procedure or an image from the measurement data and the image of the display unit is obtained. A failure processing method characterized by determining a target error, checking the camera image and / or the audio signal, and determining an environmental abnormality.