JP5099130B2 - Mobile object moving system, method and program - Google Patents

Description

[Description of related applications]
The present invention is based on the priority claim of Japanese Patent Application: Japanese Patent Application No. 2007-155967 (filed on June 13, 2007), the entire contents of which are incorporated herein by reference. Shall.
The present invention relates to a moving system in a moving body, and more particularly to a system, method, and program for correcting movement of a moving body.

  It is important to increase the movement accuracy in a moving object. As one method of increasing the movement accuracy, a method of correcting the self-position with high accuracy by observing an external index from the moving body and correcting the next movement path is used. This method is highly effective in improving movement accuracy and is widely adopted.

  However, this method cannot be applied when an index existing outside the mobile object cannot be observed due to the masking of the index. In such a case, it is necessary to move only by internal observation of a moving body such as odometry.

  Hereinafter, a method for improving the moving accuracy of the moving body even in such a situation will be described.

  In general, when moving a moving object using only internal observation, an error occurs in the amount of movement due to floor slipping, etc., so expect accuracy compared to the method of moving while observing the above external indicators. I can't. Therefore, a movement system that improves the movement accuracy by obtaining a correction amount for canceling this error in advance and appropriately correcting the movement amount is known.

  As an example of this type of mobile system, for example, Patent Document 1 discloses a configuration of a mobile robot (moving body) capable of calculating a current position with high accuracy by reducing an error in position measurement due to a change in wheel radius or the like. Yes. In Patent Document 1, route information including a distance and an angle difference between a start point and an end point of each section is recorded in advance on a mobile robot that drives a wheel and moves along a predetermined travel path. . First, the mobile robot moves through the entire section. At this time, when the end point of each section is reached, the wheel radius of the mobile robot is corrected based on the distance moved and the wheel rotation speed. And after correcting in all the sections, it moves with accuracy by moving using the wheel diameter after correction.

  As another example of the mobile system, in Patent Document 2, two markers are set in advance on the traveling floor of a mobile robot (moving body), and when the mobile robot moves and detects the first marker, Until the second marker is detected, the rotation of the wheel is measured, thereby correcting the wheel diameter, and moving using the corrected wheel diameter to move accurately. A configuration is disclosed.

JP 2006-252349 A Japanese Patent No. 2934770

The disclosures of the above Patent Documents 1 and 2 are incorporated herein by reference. The following is an analysis of the related art according to the present invention.

As a result of the study, the present inventor has found the following problems.

  In the above-described system, the user's labor required for correction value calculation increases, and the moving body cannot be moved in a short time. That is, it is difficult to calculate a correction value while suppressing an increase in travel time and the like.

  For example, in the mobile robot disclosed in Patent Document 1, it is assumed that the travel route is determined in advance. For this reason, correction values for all movement sections can be obtained in advance, and movement can be performed using the correction values during actual movement. That is, it is not necessary to sequentially calculate correction values during movement, and the mobile robot can be moved to the destination in a short time. However, the mobile robot disclosed in Patent Document 1 does not include means for determining whether correction value calculation is necessary again. For this reason, when the mobile body is driven in an environment different from the environment where the correction value is calculated, the user must recognize this and calculate the correction value again, which takes time for the user. .

  In addition, in the method and apparatus disclosed in Patent Document 2, every time the mobile robot detects a marker, the correction value is calculated. Therefore, the user basically needs to give an instruction regarding correction of movement. There is no time and effort. However, when considering that the state of the floor slip changes depending on the position of the mobile robot, it is possible to move to various places using only correction values obtained in one short section as in the example of Patent Document 2. If this is done, the accuracy of the movement will be poor and an inappropriate method will result. On the other hand, to obtain a correction value strictly for each position, it is necessary to prepare a large number of markers and calculate the correction value for each position. However, this is not a realistic method. From the above, in order to apply the method and apparatus disclosed in Patent Document 2 to a moving body that moves to various places, it is necessary to appropriately set the number of sections to be corrected. .

  Therefore, as one of the practical methods, a method of dividing a movement route into several sections having a certain length or longer so as not to be local, and obtaining a correction value for each section as in Patent Document 1. Can be considered. Thereby, a user's burden can be reduced and it can become a technique applicable also to the moving body which moves to various places. However, since the distance between the markers becomes long, it takes time to calculate the correction value.

  As described above, it has been found that neither of the methods can realize the reduction of the user's labor relating to the correction value calculation and the reduction of the moving time of the moving body (according to the result of the study by the present inventor).

  Therefore, the present invention has been made in view of the above problems, and its object is to provide a moving system, method, and program for realizing a reduction in the user's labor related to correction value calculation and a reduction in the moving time of the moving body. It is to provide.

  In order to solve the above-described problems, the invention disclosed in the present application is generally configured as follows.

A system according to one aspect of the present invention includes a correction value calculation unit that calculates a correction value used in connection with movement of a moving object, and a correction value calculation that determines whether the correction value needs to be calculated. And a necessary determination unit.
In the present invention, when the correction value calculation necessity determining unit determines that correction value calculation is unnecessary, the movement of the moving body is corrected based on a correction value recorded in the past, and the correction is performed. When the value calculation necessity determining unit determines that the correction value needs to be calculated, the correction value calculating unit calculates the correction value.

  In the present invention, the correction value calculation necessity determination unit, when correction of information related to the planned movement of the moving body is performed, before calculating the correction value corresponding to the correction, It is determined whether or not a correction value corresponding to the correction needs to be newly calculated based on at least one of the above situation, the internal information of the mobile object, and the past history information.

  In the present invention, a correction value recording unit that records the correction value calculated by the correction value calculation unit is provided, and when the correction value calculation necessity determination unit determines that the calculation of the correction value is unnecessary, Movement correction is performed using a correction value corresponding to the correction already recorded in the correction value recording unit, and the correction value calculation necessity determining unit determines that the correction value needs to be calculated. In this case, the correction value calculation unit performs correction of movement using the correction value calculated this time, and the correction value calculated this time is used as the correction value corresponding to the correction. It is good also as a structure recorded on these.

  In the present invention, the correction value calculation necessity determination unit acquires an environment information recording unit that acquires information on the surrounding environment of the mobile body, and an environment information record that records information on the environment acquired by the environment monitoring unit. And the environmental information comparison unit that compares the information on the surrounding environment acquired this time by the surrounding environment observation unit with the information on the surrounding environment already recorded in the environment information recording unit. As a result of the comparison by the comparison unit, if it can be determined that the information on the surrounding environment acquired this time and the information on the surrounding environment already recorded are the same, it is determined that the calculation of the correction value is unnecessary. If it is not possible to determine that they are the same, a configuration may be employed in which it is determined that calculation of a correction value is necessary.

  In the present invention, the correction value calculation necessity determining unit records a determination result of the moving result of the moving object by the moving result determining unit and a moving result determining unit that determines the moving result of the moving object. Information processing for performing a predetermined statistical process using the determination result of the movement result of the moving body recorded in the determination unit and the determination result recording unit, and the correction value recorded in the correction value recording unit Whether the correction value needs to be calculated according to whether the result of the statistical processing by the recorded information statistical processing unit satisfies a predetermined criterion. It is good also as a structure which judges. In the present invention, when the recording information statistical processing unit determines that the calculation of the correction value is unnecessary, the correction value calculation unit does not calculate the correction value, and the recording information statistical processing unit Select and output a predetermined correction value from among the correction values recorded in the recording unit, or output a result of arithmetic processing such as statistical processing on the correction value recorded in the correction value recording unit It may be.

  In the present invention, the correction value calculation necessity determination unit is a recent correction value recorded in the correction value recording unit in an arbitrary section moved before the section in which the mobile object is scheduled to move. And a correction value interval coincidence determining unit that determines whether or not the past correction values are the same, and whether or not the latest correction value and the past correction value are the same by the correction value interval coincidence determining unit. If it can be determined that the values are the same, it is determined that the calculation of the correction value is unnecessary. If the values cannot be determined to be the same, it is determined that the calculation of the correction value is necessary. Also good.

  In the present invention, when the correction value calculation necessity determination unit determines that the correction value calculation is unnecessary, the movement information is corrected using the correction value recorded in the correction value recording unit. A configuration may be provided that includes a route generation unit that generates a movement route of the mobile body and a movement unit that moves the mobile body according to the movement route by the route generation unit.

  In the present invention, a correction value may be recorded in the correction value recording unit corresponding to a section in which the moving body moves.

  In this invention, it is good also as a structure which is the exterior of the said mobile body and contains the correction value calculation necessity notification part which notifies that the mobile body needs calculation of a correction value.

  In the present invention, the correction value calculation necessity determination unit notifies the correction value calculation necessity notification reception unit that receives the notification signal from the correction value calculation necessity notification unit, and the reception result from the correction value calculation necessity notification reception unit. A correction value calculation necessary notification unit for determining the presence or absence of a signal, and when the presence or absence of a notification signal is determined by the correction value calculation necessity notification unit, the calculation of a correction value is necessary if there is a notification signal If it is determined that there is no notification signal, it may be determined that the calculation of the correction value is unnecessary.

  In this invention, it is good also as a structure containing the judgment result notification part which notifies the judgment result by the said correction value calculation necessity judgment part to a user.

  According to the present invention, a moving lot constituting the moving body of the moving system is provided. The moving lot may be a mobile robot that autonomously moves to a target point. Alternatively, a mobile robot that is remotely operated may be used. In addition to the mobile robot, the mobile body may be any mobile body (vehicle, flying object, etc.) that has intelligence and performs movement control.

A method according to another aspect of the present invention includes a step of controlling movement by correcting information relating to movement of a computer-controlled moving body, wherein the control step is used in connection with movement of the moving body. A correction value calculation step for calculating a value, and a correction value calculation necessity determination step for determining whether or not the correction value needs to be calculated in the correction value calculation step.
In the present invention, when the mobile object detects a position index, position information is obtained based on the position index, and when correction of the direction and path of the mobile object is necessary in relation to the position information, a correction value is calculated. In order to determine whether or not it is necessary, a determination step of acquiring information on the surrounding environment of the mobile body and determining a similarity between the information on the surrounding environment and information on the surrounding environment recorded in the storage unit in advance. In the correction value calculation necessity determination step, if there are those that can be determined to be the same as a result of the determination in the determination step, it is determined that calculation of the correction value is unnecessary, and there is no one that can be determined to be the same Determines that the calculation of the correction value is necessary, and when the calculation of the correction value is unnecessary, the corrected correction value recorded in the storage unit is used and corrected using the position information and the correction value. Move and correct using information about In the correction value calculating step, the correction value is calculated, and the position information and the information regarding the movement corrected using the calculated correction value are output to the moving means. At the same time, the calculated correction value is recorded in the storage unit.

In the method according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination step,
Whether or not the correction value needs to be calculated may be determined based on the determination result information regarding the success or failure of the movement performed by the mobile body and the correction value.

In the method according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination step,
In a section in which the mobile body has moved before a section that is scheduled to move, the latest correction value recorded in the storage unit is compared with a past correction value to determine whether or not a correction value needs to be calculated. You may do it.

In the method according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination step,
A notification signal notified to the moving body from the outside may be detected to determine whether or not a correction value needs to be calculated.

A computer program according to another aspect of the present invention is a program for controlling movement by performing correction of information related to movement of a computer-controlled moving body, and a correction value used in relation to the movement of the moving body. It comprises a program for executing a correction value calculation process for calculating and a correction value calculation necessity determination process for determining whether or not the correction value needs to be calculated in the correction value calculation step.
In the present invention, when a position index is detected, a process for obtaining position information based on the position index, and correction of the direction and path of the moving body in relation to the position information are necessary. In order to determine the presence / absence, information on the surrounding environment of the mobile body is acquired, processing for determining the similarity between the information on the surrounding environment and information on the surrounding environment recorded in advance in the storage unit, and the correction value In the calculation necessity determination process, if there is a thing that can be determined to be the same as a result of the determination of the similarity, it is determined that calculation of the correction value is unnecessary. If it is not necessary to calculate the correction value and calculate the correction value, the position information and the calculated correction value recorded in the storage unit are used to correct the movement and output it to the moving means. Processing and correction value calculation If necessary, in the correction value calculation process, the correction value is calculated, the position information and the correction information using the calculated correction value are output to the moving means and moved. The program comprises a program for causing the computer to execute a process of recording the calculated correction value in the storage unit.

In the program according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination process,
You may make it make the said computer perform the process which judges the necessity of calculation of a correction value based on the determination result information regarding the success or failure of the movement which the said mobile body performed, and the said correction value.

In the program according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination process,
In a section in which the mobile body has moved before a section that is scheduled to move, the latest correction value recorded in the storage unit is compared with a past correction value to determine whether or not a correction value needs to be calculated. You may make it make a computer perform the process to perform.

In the program according to the present invention, in order to determine whether the correction value needs to be calculated, instead of the determination process,
You may make it make the said computer perform the process which detects the notification signal notified to a mobile body from the outside and judges the necessity of calculation of a correction value.

  According to the present invention, it is possible to reduce the time and labor of the user and to move the moving body with high accuracy in a short time by determining whether or not the correction value needs to be calculated when correcting the movement.

It is a block diagram which shows the structure of embodiment of the mobile system which concerns on this invention. It is a figure which shows the structure of the 1st Embodiment of this invention. It is a flowchart which shows the operation | movement procedure of the 1st Embodiment of this invention. It is a figure which shows the structure of the 2nd Embodiment of this invention. It is a flowchart which shows the operation | movement procedure of the 2nd Embodiment of this invention. It is a figure which shows the structure of the 3rd Embodiment of this invention. It is a flowchart which shows the operation | movement procedure of the 3rd Embodiment of this invention. It is a figure which shows the structure of the 4th Embodiment of this invention. It is a flowchart which shows the 4th Embodiment of this invention. It is a figure which shows the structure of the 5th Embodiment of this invention. It is a flowchart which shows the operation | movement procedure of the 5th Embodiment of this invention. It is a figure which shows the mobile robot and charging station in one specific example of this invention. It is a flowchart which shows the process of the mobile robot in one specific example of this invention.

Explanation of symbols

100 Position index 110 Correction value calculation necessity notification means 200 Moving object 210 Index detection means 220 Self-position identification means 230 Correction value calculation means 240 Correction value recording means 250 Route generation means 260 Movement means 270 Determination result notification means 300 Correction value calculation necessity determination Means 311 Surrounding environment observation unit 312 Environmental information conversion unit 313 Environmental information comparison unit 314 Environmental information recording unit 321 Movement result determination unit 322 Determination result recording unit 323 Recorded information statistical processing unit 331 Correction value section coincidence determination unit 341 Correction value calculation necessary notification Receiving unit 342 Correction value calculation necessity notification determining unit 500 Mobile robot 501 Camera 502 Power supply terminal (back side of mobile robot)
600 Charging station 601 Feeding terminal (charging station installation)
602 Position index

  The above-described present invention will be described with reference to the accompanying drawings in order to explain in more detail. FIG. 1 is a diagram for explaining a system according to an embodiment of the present invention. The system according to an embodiment of the present invention is a moving system in which a moving body moves to a target point. When correcting a planned moving amount, the situation and internal information around the moving body 200, Based on these past histories, a correction value calculation necessity judging means (correction value calculation necessity judgment unit) 300 for judging whether or not a correction value which is a feature of correction needs to be calculated, and a correction value calculation necessity judgment The correction value calculation means (correction value calculation section) 230 for calculating the correction value and the correction value calculated by the correction value calculation means 230 when the means 300 determines that the correction value needs to be calculated. Correction value recording means (correction value recording section) 240 for recording the movement amount, and path generation means (path generation section) 250 for correcting the movement amount of the moving body 200 using the correction value and generating the moving path of the moving body 200; , Route generation means 25 It includes a moving means (moving unit) 260 for moving the movable body 200, the following movement path generated by.

  Although not particularly limited, in this embodiment, the mobile body 200 autonomously determines whether or not correction value calculation is necessary. If the correction value calculation is necessary, the mobile body 200 calculates the correction value. The correction value obtained is recorded in the correction value recording means 240.

  If there is no need to calculate the correction value, the moving body 200 moves using the correction value recorded in the past.

  Therefore, an increase in time required for movement can be suppressed and the moving body can be moved with high accuracy while reducing the user's effort for calculating the correction value.

  Further, in the mobile system according to the present invention, as shown in FIG. 2, the correction value calculation necessity determination means 300 includes a peripheral environment observation unit 311 that acquires information on the surrounding environment of the mobile body 200 and a peripheral environment observation unit 311. Environmental information comparison unit 314, which compares the environment information recording unit 314 that records information on the surrounding environment, the information on the surrounding environment acquired by the environment monitoring unit 311 and the information on the surrounding environment recorded in the environment information recording unit 314 The environment information comparison unit 313 determines that the calculation of the correction value is unnecessary when it can be determined that they are the same as a result of the comparison of the information on the surrounding environment, and cannot determine that they are the same. In this case, it is determined that a correction value needs to be calculated.

  In this aspect, the moving body 200 observes the surrounding environment and compares the information with the past surrounding environment information to estimate a change in the moving environment. According to this estimation, the moving body 200 needs to calculate a correction value. Determine whether.

  Further, in a preferable aspect of the moving system according to the present invention, as shown in FIG. 4, the correction value calculation necessity determining unit 300 determines the moving result of the moving body 200 by the route generating unit 250 and the moving unit 260. The determination unit 321, the determination result recording unit 322 that records the result of determining the movement result of the moving object 200 by the movement result determining unit 321, the determination result of the moving object 200 recorded in the determination result recording unit 322, and the correction value Predetermined statistical processing is performed using the correction value recorded in the recording means 240, and whether or not the correction value needs to be calculated according to whether or not the statistical processing result satisfies a predetermined determination criterion. If it is determined that correction value calculation is not necessary, a recorded information statistical process for calculating a correction value to be used by the route generation unit 250 using the correction value recorded in the correction value recording unit 240 is used. Including a part 323, a.

  In this aspect, the mobile body 200 estimates the change in the mobile environment based on the variance or average in the past correction values, the success rate in the past movement determination result, etc., and based on the estimation of the change in the mobile environment, It is determined whether a correction value needs to be calculated.

  Further, in a preferred aspect of the mobile system according to the present invention, as shown in FIG. 6, the correction value calculation necessity determining means 300 is used in an arbitrary section where the mobile body 200 has moved before the section scheduled to move. A correction value section match determination unit 331 that determines whether or not the latest correction value recorded in the correction value recording unit 240 and the past correction value are the same is included. The correction value section coincidence determination unit 331 determines whether or not the latest correction value recorded in the correction value recording unit 240 and the past correction value are the same as a result of the determination. If it is determined that the calculation of the value is unnecessary and it cannot be determined that the values are the same, it is determined that the correction value needs to be calculated.

  In this aspect, the moving body 200 moves the section scheduled to move from now on by comparing the latest correction value and the past correction value in an arbitrary section moved before the section scheduled to move from now on. Before the determination, a change in the mobile environment is estimated, and it is determined whether a correction value needs to be calculated based on the estimation of the change in the mobile environment.

  Further, in a preferable aspect of the mobile system according to the present invention, as shown in FIG. 8, it is necessary to calculate a correction value that is outside the mobile body 200 and notifies the mobile body 200 that a correction value needs to be calculated. Notification means 110 is provided. The correction value calculation necessity determining means 300 includes a correction value calculation necessity notification receiving section 341 that receives the notification signal from the correction value calculation necessity notifying section 110 and the presence / absence of a notification signal from the reception result by the correction value calculation necessity notification receiving section 341. A correction value calculation necessary notification determining unit 342 that determines whether there is a notification signal as a result of determining the presence / absence of the notification signal by the correction value calculation necessary notification determining unit 342, it is necessary to calculate a correction value. If it is determined that there is no notification signal, it is determined that calculation of the correction value is unnecessary.

  In this aspect, since the correction value calculation necessity notification unit 110 notifies the moving body 200 that the moving environment of the moving body has changed outside the moving body 200, the moving body 200 can be easily corrected. It can be determined whether or not a value needs to be calculated.

<First Embodiment>
FIG. 2 is a diagram showing the configuration of the first exemplary embodiment of the present invention. Referring to FIG. 2, the first embodiment of the present invention includes a moving body (mobile robot) 200 that moves, and a position index 100 that gives information on the relative position of the moving body 200 with respect to the moving body 200. It has.

  The mobile body 200 observes and detects the position index 100, and the self-position identification for obtaining the relative position between the position index 100 and the mobile body 200 based on the detection result (index detection information) of the index detection means 210. Means 220; correction value calculation necessity judging means (correction value calculation necessity judging section) 300 for judging whether or not a correction value needs to be calculated; correction value calculation means (correction value calculating section) 230 for performing correction value calculation; A correction value recording unit (correction value recording unit) 240 that records the correction value calculated by the correction value calculation unit 230, and a route generation unit (route) that generates route information using the correction value recorded in the correction value recording unit 240. Generating unit) 250, a moving unit (moving unit) 260 for moving the moving body 200 according to the route information generated by the correction value calculating unit 230 and the route generating unit 250, Including. Each of these operates as follows.

  The position index 100 issues an index signal for the mobile body 200 to perform self-position identification to the mobile body 200.

  For example, the position index 100 may be configured in an asymmetric arrangement with three infrared LED (Light Emitting Diode) light sources. Note that the number and arrangement of the infrared LED light sources are not limited to such a configuration, and any number can be used as long as the self-position identifying unit 220 always uniquely determines the self-position of the moving body 200. It may be arranged. The position index 100 may be an index that can be captured visually, such as an infrared LED light source, a two-dimensional pattern, a visible light source, or a sound source, a radio wave source, a magnetic field source, a laser surveying instrument, or the like. There may be.

  The index detection unit 210 is mounted on the moving body 200, for example, and generates index detection information when detecting an index signal from the position index 100.

  The index detection unit 210 supplies the generated index detection information to the self-position identification unit 220.

  When the position index 100 is an infrared LED light source, the index detection unit 210 may be configured by a parallel stereo model using two CCD (Charge Coupled Device) cameras.

  The index detection unit 210 obtains an image of the infrared LED light source and performs image processing such as binarization and labeling to detect the infrared LED light source on the image, and on the image of the infrared LED light source. You may produce | generate the index detection information which shows a position. In the index detection means 210, the number of CCD cameras is not limited to two and any number may be used. In the index detection unit 210, another imaging device may be used instead of the CCD camera. Furthermore, the index detection unit 210 is configured to be able to observe the index signal corresponding to the configuration of the position index 100, such as a microphone, a radio wave receiver, or a magnetic field detector, without being limited to the imaging device.

  In the index detection unit 210, the index detection information is generated by an image matching process such as template matching or by physically mounting an infrared filter on the camera so that only the infrared LED light source can be imaged. Good.

  Further, the index detection unit 210 may detect a predetermined sound wave when the position index 100 emits a sound wave in association with the index signal from the position index 100. When the position index 100 emits radio waves, radio wave analysis processing may be performed. Alternatively, when the position index 100 generates a magnetic field, a magnetic field change detection process or the like may be performed. When it is difficult to mount the index detection unit 210 on the mobile body 200, the index detection unit 210 may be mounted on another computer that can communicate with the mobile body 200.

  The self-position identification unit 220 is mounted on, for example, the moving body 200, calculates the relative position of the moving body 200 with respect to the position index 100 from the index detection information, and generates position information.

  The self-position identification unit 220 receives the index detection information from the index detection unit 210 and outputs the position information to the correction value calculation unit 230 and the route generation unit 250.

  As an example, it is assumed that the index detection information input from the index detection unit 210 to the self-position identification unit 220 is the positions of three infrared LED light sources on the image. At this time, the self-position identifying unit 220 first uses each position of the infrared LED light source on the image to thereby set each position of the infrared LED light source in the three-dimensional moving body coordinate system set with the moving body 200 as a reference. Ask for.

  Next, the self-position identification unit 220 calculates the relative positional relationship of the moving body 200 with reference to the position of one infrared LED light source based on the positional relationship of the three infrared LED light sources, and generates position information. To do.

  In addition, Cassini's method (general reference: “real-time self-position identification method based on two landmark orientation measurements and dead reckoning”), Journal of the Robotics Society of Japan, Vol. , Pp. 311-320, 2005), etc., may be used instead of the position identification method that can specify the position of the moving body 200.

  In the calculation of the relative position, the reference coordinate system is not limited to the moving body coordinate system, and may be replaced with a coordinate system based on an arbitrary point.

  Further, the self-position identification unit 220 uses a sound source position estimation method or the like when a sound wave is used as the position index 100. When radio waves are used for the position index 100, a radio wave source identification method or the like is used. That is, the self-position identification unit 220 performs processing suitable for the index detection information by the index detection unit 210.

  The correction value calculation necessity determination unit 300 determines whether or not a correction value needs to be calculated by comparing information on the surrounding environment of the mobile body 200 with information on the surrounding environment recorded in the past, and calculates the correction value. A flag indicating whether or not to perform is generated.

  The correction value calculation necessity determination means 300 inputs information on the surrounding environment of the moving body 200. The correction value calculation necessity determination unit 300 outputs a flag indicating whether or not to calculate a correction value to the correction value calculation unit 230 or the route generation unit 250, and uses the ID value attached to the surrounding environment information as the correction value recording unit 240. Output to.

  More specifically, the correction value calculation necessity determination unit 300 converts the surrounding environment observation unit 311 that acquires the surrounding environment of the moving body 200 and the information acquired by the surrounding environment observation unit 311 so that comparison is easy. Environment information conversion unit 312 that performs the comparison, and the environment information that is converted by the environment information conversion unit 312 and the environment information that has been recorded in the past are compared, and an environment for generating a flag indicating whether or not to perform correction value calculation is generated. As a result of comparing the information on the surrounding environment acquired by the surrounding environment observation unit 311 with the information comparing unit 313 and the information on the surrounding environment recorded in the past by the environment information comparing unit 313, it is determined that there is no same environment. An environment information recording unit 314 that records the environment information with the ID value added thereto. Each of the above parts operates as follows.

  The surrounding environment observation unit 311 observes the surrounding environment of the moving body 200.

  The surrounding environment observation unit 311 receives the observation of the surrounding environment of the moving body 200 as an input, and outputs the surrounding environment information to the environment information conversion unit 312. For example, the surrounding environment observation unit 311 may be an imaging device such as a camera. Alternatively, the surrounding environment observation unit 311 may be a microphone, a radio wave receiver, a magnetic field detector, or the like. Note that the surrounding environment observation unit 311 may also be used in combination with that constituting the index detection unit 210. In this case, the hardware configuration becomes simple and can be realized at low cost.

  The environment information conversion unit 312 performs conversion processing on the surrounding environment information obtained by the surrounding environment observation unit 311 so that the comparison processing in the environment information comparison unit 313 is easy.

  The environment information conversion unit 312 receives the information on the surrounding environment acquired by the surrounding environment observation unit 311 and outputs the converted information on the surrounding environment to the environment information comparison unit 313. For example, when the surrounding environment observation unit 311 is a camera, the obtained surrounding environment information is an image.

  The environment information conversion unit 312 first classifies each pixel of the image obtained as information on the surrounding environment for each of n preset colors, and calculates the ratio of the number of pixels in the class to the total number of pixels of the image. Ask for all classes.

  The environment information conversion unit 312 may perform the conversion process by generating an n-dimensional vector whose component is the ratio of the number of pixels in each class.

  In addition, the environment information conversion unit 312 may perform a conversion process so as to be suitable for the comparison process in the environment information comparison unit 313, such as performing a conversion process so as to be a scalar value.

  In addition, the environment information conversion unit 312 may output the surrounding environment information as it is to the environment information comparison unit 313 without performing the conversion process.

  For example, the environment information comparison unit 313 is mounted on the mobile body 200 and compares the information on the surrounding environment converted by the environment information conversion unit 312 with the information on all the surrounding environments recorded in the environment information recording unit 314. Do. Although not particularly limited, in the present embodiment, the comparison of the surrounding environment is based on the difference between the information on the surrounding environment converted by the environment information converting unit 312 and the information on the surrounding environment recorded in the environment information recording unit 314. This is performed by determining whether or not a predetermined condition is satisfied. If the certain condition is satisfied, it is determined that the environment is the same, and if not satisfied, it is determined that the environment is not the same.

  If the environment information comparison unit 313 determines that there is no same environment, the environment information comparison unit 313 determines that correction value calculation is necessary, generates a flag for performing correction value calculation, and converts the environment information. The ID value is newly added to the information on the surrounding environment converted by the unit 312.

  On the other hand, if the environment information comparison unit 313 determines that there is the same environment, it determines that there is no need to calculate the correction value, generates a flag that does not calculate the correction value, and determines that the environment information recording unit determines that the same is the same. The ID value of the information on the surrounding environment recorded in 314 is acquired.

  The environment information comparison unit 313 receives as input the information on the surrounding environment converted by the environment information conversion unit 312, the information on the surrounding environment recorded in the environment information recording unit 314, and the ID value attached thereto. .

  If the environment information comparison unit 313 determines that the correction value needs to be calculated, a flag for calculating the correction value is output to the correction value calculation unit 230 and is input from the environment information conversion unit 312. And the newly added ID value are output to the environment information recording unit 314. Furthermore, the environment information comparison unit 313 outputs only this ID value to the correction value recording unit 240.

  If the environmental information comparison unit 313 cannot determine that correction value calculation is necessary, a flag that does not perform correction value calculation is output to the route generation unit 250, and it is determined that the information is the same when comparing the surrounding environment information. The ID value of the information on the surrounding environment recorded in the environment information recording unit 314 is output to the correction value recording unit 240.

  For example, assume that the environment information conversion unit 312 generates a vector.

When the environment information comparison unit 313 receives the vector (a) from the environment information conversion unit 312, the environment information comparison unit 313 receives the ID value (i) stored in the environment information recording unit 314 and the vector (b _i ). Read all.

In order to compare the surrounding environments, the norm of the difference between a and b _i is obtained for each i, and this is set as the environment similarity S _i . That is, _Si is obtained by the equation (1).
S _i = | a−b _i | (1)

Next, the minimum environmental similarity S _min is obtained from all i, and it is checked whether or not S _min is within a predetermined range ε to Ε (ε <Ε). That is, the minimum environmental similarity S _min is obtained from the equation (2), and it is confirmed whether the equation (3) is satisfied.
S _min = min (S _i ) (2)

ε <S _min <Ε (3)

However, the operation value min of Expression (2) is the minimum value of S _i for all i.

When the minimum environment similarity S _min is within a predetermined range, that is, when Expression (3) is satisfied, it is determined that the information on the surrounding environment is the same, and a flag that does not calculate the correction value is routed. Output to the generation means 250.

  Further, the ID value i of the environmental similarity that has become the minimum environmental similarity is output to the correction value recording means 240.

On the other hand, when the minimum environment similarity S _min is not within the predetermined range, that is, when the expression (3) is not satisfied, it is determined that the information on the surrounding environment is not the same, and the flag for performing the correction value calculation is set as the correction value. It outputs to the calculation means 230. In addition, a new ID value is assigned to the vector a and output to the environment information recording unit 314. Further, this ID value is output to the correction value recording means 240.

  The environment information comparison unit 313 may be implemented by a remote computer or the like that can communicate with the mobile object 200. The environmental similarity may be obtained by using another calculation method such as an inner product of vectors.

  In addition, the range of the environmental similarity used for determining whether or not the surrounding environment is the same may be any suitable range according to the calculation method of the environmental similarity and the input characteristics of the surrounding environment observation unit 311.

  Note that when the surrounding environment observation unit 311 directly inputs information on the surrounding environment of the position index 100, for example, evaluation is performed using an image matching method such as template matching, depending on the information generated by the surrounding environment observation unit 311. Alternatively, a suitable evaluation method may be used.

  The environment information recording unit 314 is implemented by the storage device of the moving body 200, and records the ID value attached to the surrounding environment information and the surrounding environment information by the environment information comparing unit 313.

  The environment information recording unit 314 receives the ID value and the surrounding environment information from the environment information comparison unit 313 as inputs, and outputs the recorded information to the environment information comparison unit 313.

  Note that the environment information recording unit 314 may be implemented by a storage device on a remote computer that can communicate with the mobile unit 200. Also, it is desirable to store the information on the surrounding environment to be stored in accordance with the format of information generated by the surrounding environment observation unit 311 such as vectors and image data, and information converted by the environment information conversion unit 312. In addition, other information such as date and time may be added and recorded in addition to the ID value for facilitating information extraction and the like.

  When the correction value calculation unit 230 receives the flag for calculating the correction value, the correction value calculation unit 230 first generates route information for calculating the correction value based on the position information, and moves by the moving unit 260.

  When the movement of the moving body 200 is completed, the position information is acquired again, and the correction value is calculated based on the position information before and after the movement of the moving body 200.

  Further, in the correction value calculation means 230, the position information by the self-position identification means 220 and the flag for performing correction value calculation by the correction value calculation necessity determination means 300 are input, and the route information for performing correction value calculation is transferred to the movement means 260. And the calculated correction value is output to the correction value recording means 240.

  For example, the correction value calculation unit 230 generates a path for rotating the moving body 200 in front of the position index 100 as a path for performing correction value calculation, and outputs the path to the movement unit 260. At this time, the designated rotation amount is obtained so that the moving body 200 faces the position index after the end of the rotation.

  When the rotation of the moving body 200 is completed, the correction value calculation unit 230 obtains the position information again, obtains the actual rotation amount from the position information before and after the movement, and the ratio of the actual rotation amount to the rotation amount specified as the correction value Ask for.

  The correction value calculation unit 230 generates a path for calculating the correction value, not limited to rotation, but may be a straight path, a turn, or a combination of these paths.

The correction value is not only the ratio of the actual rotation amount to the specified rotation amount,
-Correcting the wheel diameter of the moving body 200 using the rotation speed and rotation angle,
-Calculate the correction value by dynamic analysis using the weight, speed, angular velocity, acceleration, angular acceleration of the moving body 200, gravitational acceleration, contact area between the wheel and the ground, coefficient of friction with the ground, etc. Any material that is suitable for the movement control of the moving body 200 is optional.

  The correction value recording unit 240 is implemented by the storage device of the moving body 200. When the correction value calculation necessity determination unit 300 determines that correction value calculation is necessary, the environment information comparison unit 313 performs information on the surrounding environment. The ID value newly added to the information and the correction value obtained by the correction value calculation means 230 are recorded as a set.

  When the correction value calculation necessity determination unit 300 determines that the correction value calculation is not necessary, the correction value recording unit 240 records the correction value recording unit 240 in the environment information recording unit 314 that has been determined to be the same environment by the environment information comparison unit 313. The correction value paired with the ID value that matches the ID value attached to the surrounding environment information and the ID value recorded in the correction value recording means 240 is extracted.

  The correction value recording unit 240 receives the ID value from the environment information comparison unit 313 and the correction value from the correction value calculation unit 230 as input. If the ID value matches the ID value from the environment information comparison unit 313, the correction value recording unit 240 records the correction value recording unit 240 in the correction value recording unit 240. The correction value paired with the set ID is output to the route generation unit 250.

  For example, the correction value recording unit 240 may be implemented by a storage device of a remote computer that can communicate with the moving body 200.

  In the correction value recording unit 240, information stored as a pair with the correction value may be stored in accordance with the format of information to be compared by the environmental information comparison unit 313, such as environmental image data.

  When the route generation unit 250 receives a flag that does not perform correction value calculation, the route generation unit 250 generates route information for moving the moving body 200 based on the position information, and corrects the route information using the correction value by the correction value recording unit 240. .

  More specifically, the path generation unit 250 receives as input the position information from the self-position identification unit 220, the flag for not performing correction value calculation by the correction value calculation necessity determination unit 300, and the correction value from the correction value recording unit 240. The route information corrected using the position information and the correction value is output to the moving unit 260.

  For example, the route generation unit 250 calculates a target rotation amount so that the moving body 200 faces backward with respect to the position index 100 based on the position information. Next, when the correction value is the ratio of the movement amount to be specified with respect to the target movement amount, the route generation unit 250 multiplies the target rotation amount by the reciprocal of the correction value to obtain the rotation amount to be specified. Obtained and output to the moving means 260.

  The route generation means 250 is not limited to such a configuration, and straight travel or turning may be added to the generated route. Further, when there is an obstacle on the moving route, the route generation unit 250 sets a new waypoint to bypass the obstacle on the moving route, and similarly to the waypoint. For example, route information may be generated, or a movement strategy suitable for the moving body 200 may be used.

  The route correction method is preferably based on a correction value calculation method in the correction value calculation means 230. The moving means 260 moves the moving body 200 according to the route information.

  The moving unit 260 receives the position information output from the self-position identifying unit 220 and the route information output from the route generating unit 250 as inputs.

  For example, the moving means 260 may be configured to be suitable when the moving body moves, such as two electric wheels. In addition, the present invention may be applied to a transporter moving on a rail, a biped robot, a flying object, and the like.

  Next, the overall operation of this exemplary embodiment will be described in detail with reference to the flowchart of FIG.

  The starting point A0 of the flowchart is a state immediately after the moving body 200 has moved by some means (after the path corrected in accordance with the procedure of the flowchart of FIG. 3 or the path for calculating the correction value). Including after moving).

  First, an index signal is obtained from the position index 100, and index detection information is obtained by the index detection means 210 (step A1 in FIG. 3).

  Next, position information is obtained from the index detection information by the self-position identifying means 220 (step A2).

  Here, the moving body 200 checks whether or not the section to the next target position is a section that needs to be corrected (step A3).

  If it is a section in which correction is not required (No branch at step A3), the process exits from this flow.

  If the section that needs to be corrected has been reached (Yes branch at step A3), information on the surrounding environment is obtained from the surrounding environment observation unit 311 (step A4).

  Then, the environment information conversion unit 312 converts the information of the surrounding environment so that the environment information comparison unit 313 can easily compare the information (step A5), and the environment information comparison unit 313 records the information in the environment information recording unit 314. It is checked whether there is information that can be determined to be the same as the information on the surrounding environment in step A5 from the information on the surrounding environment (step A6).

  If there is nothing that can be determined to be the same in step A6, a correction value is calculated by the correction value calculation means 230 (step A7), and the calculated correction value is used as information on the surrounding environment obtained at that time. The correction value is recorded by the correction value recording means 240 (step A8).

  If there is something that can be determined to be the same in step A6, the route generation means 250 performs correction using the correction value associated with the information of the surrounding environment determined to be the same (step A9). .

  Next, the effect of this embodiment will be described.

  In the present embodiment, the surrounding environment of the moving body 200 is observed and compared with information of the surrounding environment recorded in the past, thereby estimating the change in the moving environment and determining whether or not the correction value needs to be calculated. It is configured.

  For this reason, even when the position index 100 itself is moved to another location, the moving body 200 can recognize this change, and can appropriately determine whether or not a correction value needs to be calculated.

<Second Embodiment>
Next, a second embodiment of the present invention will be described. FIG. 4 is a diagram showing the configuration of the second exemplary embodiment of the present invention. Referring to FIG. 4, the second embodiment of the present invention includes a moving body (mobile robot) 200 that moves, and a position index 100 that gives information on the relative position of the moving body 200 to the moving body 200. It has. The moving body 200 includes the same configuration as that of the first embodiment described above. Each of these means operates as follows.

  The position index 100 and the index detection means 210 perform the same operation as in the first embodiment and have the same input / output as in the first embodiment.

  The self-position identification unit 220 performs the same operation as in the first embodiment. The self-position identification unit 220 has the same input / output as that of the first embodiment, and further outputs position information to the correction value calculation necessity determination unit 300.

  Based on the position information from the self-position identifying unit 220, the correction value calculation necessity determining unit 300 determines whether or not the route can be moved along the route corrected by the route generating unit 250 and the moving unit 260. Record the judgment result.

  The correction value calculation necessity determination means 300 determines whether or not correction value calculation is necessary from recording of the determination result of the movement result and recording of the correction value, and generates a flag indicating whether or not correction value calculation is to be performed. To do.

  The correction value calculation necessity determination unit 300 inputs the position information from the self-position identification unit 220 and the correction value recorded in the correction value recording unit 240.

  Further, the correction value calculation necessity determination unit 300 outputs a flag indicating whether or not to perform correction value calculation to the correction value calculation unit 230 or the route generation unit 250.

More specifically, the correction value calculation necessity determination unit 300 includes a movement result determination unit 321 that determines whether or not the moving body 200 has moved along the route corrected by the route generation unit 250 and the movement unit 260;
Based on the determination result recording unit 322 that records the determination result information in the movement result determination unit 321, the determination result information recorded in the determination result recording unit 322, and the correction value recorded in the correction value recording unit 240. A recording information statistical processing unit 323 for determining an appropriate correction value based on a past correction value. Each of the above parts operates as follows.

  The movement result determination unit 321 moves the route corrected by the moving body 200 by the route generation unit 250 and the movement unit 260, and indicates the determination result of the success or failure of the movement based on the position information before and after the movement. Judgment result information is generated.

  The movement result determination unit 321 receives position information from the self-position identification unit 220 as input, and outputs determination result information indicating determination of success or failure of movement to the determination result recording unit 322.

  For example, assume that the target movement amount is 10 cm in a straight line and the movement amount to be instructed by the route correction is 12 cm in a straight line.

  The moving unit 260 is instructed to move straight 12 cm, and the movement result determination unit 321 obtains a position difference in the position information before and after the movement starts. If it can be confirmed that there has been a straight movement of 10 cm, the determination result information is a successful movement.

  On the other hand, if it is not possible to confirm a straight 10 cm movement, the determination result information indicates a movement failure.

  In the above example, the determination regarding the target movement amount and the actual movement amount is more than the evaluation of the perfect match between the actual movement amount and the target movement amount in consideration of the influence of the position information error. It is more realistic to evaluate a value close to the target movement amount.

  Therefore, in the present embodiment, if the difference between the actual movement amount and the target movement amount is equal to or less than a predetermined value, a determination method with a wide range such as determination of coincidence may be used. .

  The determination result recording unit 322 is implemented by a storage device of the moving body 200 and records determination result information by the movement result determination unit 321.

  The determination result recording unit 322 receives the determination result information from the movement result determination unit 321 as input, and outputs the recorded determination result information to the recording information statistical processing unit 323.

  Note that the determination result recording unit 322 may be implemented by a storage device of a remote computer that can communicate with the mobile object 200.

  Further, the determination result information recorded by the determination result recording unit 322 may be recorded with other information such as date and time added in order to facilitate operations such as information extraction.

  The recorded information statistical processing unit 323 performs a process of determining whether or not a correction value needs to be calculated from the determination result information recorded in the determination result recording unit 322 and the correction value recorded in the correction value recording unit 240. .

  When the recording information statistical processing unit 323 determines that the correction value needs to be calculated, the recording information statistical processing unit 323 generates a flag for performing the correction value calculation. On the other hand, if the recorded information statistical processing unit 323 cannot determine that the correction value needs to be calculated, the recorded information statistical processing unit 323 obtains a correction value to be used for correcting the route by the route generation unit 250 and generates a flag that does not calculate the correction value. .

  More specifically, the recorded information statistical processing unit 323 receives the determination result information recorded in the determination result recording unit 322 and the correction value recorded in the correction value recording unit 240 as inputs.

  When the recording information statistical processing unit 323 determines that calculation of the correction value is necessary, the recording information statistical processing unit 323 outputs a flag for calculating the correction value to the correction value calculation unit 230.

  On the other hand, if the recorded information statistical processing unit 323 cannot determine that the correction value needs to be calculated, the recording information statistical processing unit 323 outputs a correction value used for correcting the route and a flag that does not calculate the correction value to the route generating unit 250. .

The recorded information statistical processing unit 323, for example, in the recorded determination result information,
・ Movement has been successful more than 4 times in the past 5 times, and
-In the recorded correction values, the dispersion of the correction values in the past five times is smaller than the predetermined value.
In this case, it is determined that the correction has a correct and stable effect, and it is determined that it is not necessary to calculate a correction value.

  Further, the recorded information statistical processing unit 323 obtains a correction value used for path correction as an average value of the past five times in the recorded correction value. In other cases, the recorded information statistical processing unit 323 determines that the correction value needs to be calculated.

  Note that the recorded information statistical processing unit 323 may set the number of recorded information samples and the number of successes used in determining whether or not a correction value is necessary. In addition to evaluating the dispersion of correction values, other evaluation criteria such as the width between the maximum value and the minimum value may be used.

  In the recorded information statistical processing unit 323, the evaluation criteria may be changed according to the number of information recorded in the determination result recording unit 322.

  In the recorded information statistical processing unit 323, the correction value to be output may be an intermediate value of the correction value or a correction value recorded last.

  The correction value calculation unit 230 performs the same operation as that of the first embodiment, and has the same input / output as that of the first embodiment.

  The correction value recording unit 240 is implemented by, for example, a storage device of the moving body 200, and records the correction value by the correction value calculation unit 230.

  The correction value recording unit 240 receives the correction value calculated by the correction value calculation unit 230, and when the recording information statistical processing unit 323 determines that the calculation of the correction value is unnecessary, the path in the recording information statistical processing unit 323 The recorded information is output to the recorded information statistical processing unit 323 according to the calculation content of the correction value used for correction.

  For example, the correction value recording unit 240 may be implemented by a storage device of a remote computer that can communicate with the mobile body (mobile robot) 200.

  Further, in the correction value recording means 240, the correction value to be recorded may be recorded by adding other information such as date and time in order to facilitate information extraction and the like.

  The route generation means 250 and the movement means 260 perform the same operation as in the first embodiment, and have the same input / output as in the first embodiment.

  Next, the overall operation of the present exemplary embodiment will be described in detail with reference to the flowchart of FIG.

  Note that the start point B0 of the flowchart includes a state immediately after the moving body 200 moves by some means (after moving the route corrected by the flowchart or after moving the route for calculating the correction value). ).

  Steps B1 to B3 in FIG. 5 are the same processes as steps A1 to A3 in FIG. 3 showing the overall operation in the first embodiment.

  When the section that needs to be corrected has been reached, the recording information statistical processing unit 323 performs correction based on the determination result information recorded in the determination result recording unit 322 and the correction value recorded in the correction value recording unit 240. It is determined whether or not a value needs to be calculated (step B4).

  In step B4, when the recording information statistical processing unit 323 determines that the correction value needs to be calculated, the correction value calculation unit 230 calculates the correction value (step B5), and the calculated correction value is calculated. Recording is performed by the correction value recording means 240 (step B6).

  In step B4, if the recorded information statistical processing unit 323 cannot determine that the correction value needs to be calculated, the route generation unit 250 uses the correction value obtained by the recorded information statistical processing unit 323 to determine the route. Correction is performed and movement is performed (step B7).

  After the movement, the movement result determination unit 321 determines the movement result (step B8).

  Next, the effect of this embodiment will be described.

  In the present embodiment, it is configured to determine whether or not a correction value needs to be calculated based on the determination result information recorded in the determination result recording unit 322 and the correction value recorded in the correction value recording unit 240. Therefore, even when the position index 100 that has been installed at a certain position for a long time is moved to another location, the moving body 200 can detect the change from the above information, and the correction value It is possible to appropriately determine the necessity of calculation.

  Further, in this embodiment, when the position index 100 is set again for a long time at the place after the change, the mobile unit 200 records a large amount of the information at the place, and gradually adapts to the new environment. As a result, the robot moves without calculating a correction value.

<Third Embodiment>
Next, a third embodiment of the present invention will be described. FIG. 6 is a diagram showing the configuration of the third exemplary embodiment of the present invention. Referring to FIG. 6, the third embodiment of the present invention includes a moving body (mobile robot) 200 that moves, and a position index 100 that gives information on the relative position of the moving body 200 to the moving body 200. I have. The moving body 200 includes the same configuration as that of the first embodiment. Each of these operates as follows.

  The position index 100 and the index detection means 210 perform the same operation as in the first embodiment and have the same input / output as in the first embodiment.

  The self-position identification unit 220 performs the same operation as that of the second embodiment and has the same input / output as that of the second embodiment.

  The correction value calculation necessity determination means (correction value calculation necessity determination unit) 300 is the latest correction value recorded in the correction value recording means 240 in an arbitrary section where the mobile body 200 has moved before the section scheduled to move. And a past correction value are determined to be the same, and a flag indicating whether or not correction value calculation is to be performed is generated for a section scheduled to move from now on.

  The correction value calculation necessity determination means 300 has the same input / output as that of the second embodiment.

  It should be noted that the correction value calculation necessity determination means 300 has the latest correction value and the past correction value recorded in the correction value recording means 240 in an arbitrary section in which the moving body 200 has moved before the section scheduled to move. A correction value section coincidence determining unit 331 that determines whether or not they are the same is included.

  First, the correction value section coincidence determination unit 331 clarifies the section in which the mobile body 200 is scheduled to move from now on, based on the position information from the self-position identification unit 220.

  Next, the correction value interval coincidence determination unit 331 determines whether or not the latest correction value recorded in the correction value recording unit 240 and the past correction value are the same in any interval moved before this interval. to decide.

  When the correction value section coincidence determination unit 331 determines that the latest correction value and the past correction value are the same, it determines that the calculation of the correction value is unnecessary, and sets a flag that does not calculate the correction value. At the same time, the past correction value recorded in the correction value recording means 240 in the same section as the section where the mobile body 200 is scheduled to move is obtained.

  Further, when the correction value section coincidence determination unit 331 cannot determine that the latest correction value and the past correction value are the same, it determines that the correction value needs to be calculated and generates a flag for calculating the correction value. .

  The correction value section coincidence determination unit 331 receives the position information from the self-position identification unit 220 and the correction value recorded by the correction value recording unit 240 as inputs.

  If the correction value interval coincidence determining unit 331 determines that the correction value needs to be calculated, it outputs a flag for calculating the correction value to the correction value calculating means 230.

  When the correction value interval coincidence determining unit 331 cannot determine that the correction value needs to be calculated, it outputs a flag that does not calculate the correction value to the correction value recording means 240, and in the interval that is scheduled to move from now on, The past correction values recorded in the correction value recording unit 240 are output to the route generation unit 250.

  As an example, a case where the moving body 200 continuously moves in a certain section XY and section YZ will be described. Here, the moving body 200 has moved continuously in the sections XY and YZ in the past, and the correction values used in each section at that time are recorded in the correction value recording means 240, respectively. Shall.

  First, the moving body 200 calculates a correction value by the correction value calculation unit 230 and records it in the correction value recording unit 240 before moving in the section XY. Then, the route generation unit 250 corrects the route information using the correction value, and moves the section XY.

  Next, when the correction value section coincidence determination unit 331 moves in the section YZ, the correction value calculated immediately before being recorded in the correction value recording unit 240 for the section XY is the same as the correction value of the past section XY. It is determined whether or not.

  When the correction value section coincidence determination unit 331 determines that the correction value calculated immediately before is the same as the past correction value, it is determined that the correction value need not be calculated and is recorded in the correction value recording unit 240. Using the correction value of the past section YZ, the route generation unit 250 performs correction and moves.

  When the correction value interval coincidence determination unit 331 cannot determine that the correction value calculated immediately before is the same as the past correction value, it is determined that the correction value needs to be calculated, and the correction value calculation unit 230 calculates the correction value. I do.

  In the present embodiment, instead of considering only one section immediately before the section scheduled to move in the future, an arbitrary section of the section preceding the section scheduled to move in the future is to be evaluated. It is good. Further, not only one section but a plurality of sections may be evaluated.

  Further, in the present embodiment, it is more realistic to evaluate that the values are close to each other than to evaluate a complete match of correction values due to an error in position information. For this reason, if the difference between these correction values is equal to or less than a predetermined value, a determination method with a width such as determination of coincidence may be used.

  In addition, when there are a plurality of past correction values of the same movement section recorded in the correction value recording means 240 used in the correction value comparison, a plurality of values selected according to a predetermined standard are used. An average of correction values may be used.

  When receiving the flag for calculating the correction value, the correction value calculating unit 230 first generates route information for calculating the correction value based on the position information, and moves by the moving unit 260. When the movement is completed, the position information is acquired again, and the correction value is calculated based on the position information before and after the movement, and at the same time, the movement section where the correction value is calculated is obtained.

  The correction value calculation unit 230 receives the position information output from the self-position identification unit 220 and the flag for calculating the correction value output from the correction value calculation necessity determination unit 300 as input, and calculates the correction value. Is output to the moving means 260, and the calculated correction value and the moving section where the correction value is calculated are paired and output to the correction value recording means 240. Other than this, the correction value calculation means 230 is the same as that of the second embodiment.

  The correction value recording unit 240 is implemented by, for example, the storage device of the moving body 200, and records the correction value by the correction value calculation unit 230 and the moving section in which the correction value is calculated as a set.

  The correction value recording means 240 receives as input the correction value from the correction value calculation means 230 and the movement section in which the correction value is calculated. The correction value recording unit 240 outputs the recorded information to the correction value section coincidence determination unit 331. Other than this, the correction value recording means 240 is the same as that of the second embodiment.

  The route generation means 250 and the movement means 260 each perform the same operation as in the first embodiment, and have the same input / output as in the first embodiment.

  Next, the overall operation of the present embodiment will be described in detail with reference to the flowchart of FIG.

  The starting point C0 of the flowchart includes a state immediately after the moving body 200 has moved by some means (after moving the path corrected by the flowchart or after moving the path for calculating the correction value). ).

  Steps C1 to C3 in FIG. 7 are the same processes as steps A1 to A3 in FIG. 3 showing the overall operation in the first embodiment.

  When the section that needs to be corrected has been reached, the correction value section coincidence determining unit 331 causes the correction value recording unit 240 to store the correction value in any section where the mobile body 200 has moved before the section scheduled to move. The recorded recent correction value is compared with the past correction value to determine whether or not the correction value needs to be calculated (step C4).

  In step C4, when it is determined that the correction value interval coincidence determining unit 331 needs to calculate the correction value, the correction value is calculated by the correction value calculation unit 230 (step C5). Then, the correction value recording means 240 records the correction value as a pair with the calculated movement section (step C6).

  In step C4, if the correction value interval coincidence determining unit 331 cannot determine that the correction value needs to be calculated, the correction value obtained by the correction value interval coincidence determining unit 331 is used for the route generation unit 250. The path is corrected to move (step C7).

  Next, the effect of this embodiment will be described.

  In the present embodiment, the correction value section coincidence determination unit 331 allows the correction value recording means 240 to record the latest correction value and the past in an arbitrary section where the mobile body 200 has moved before the section scheduled to move. By comparing the correction values, it is determined whether the correction value needs to be calculated. For this reason, once the correction value calculation is performed, it is possible to pre-determine the necessity of calculating the correction value in another movement section.

  In addition, according to the present embodiment, when the movement route is composed of multiple sections, the above-described effect is further increased because the effort for determining whether or not the correction value needs to be calculated for each section is reduced.

<Fourth embodiment>
Next, a fourth embodiment of the present invention will be described. FIG. 8 is a diagram showing the configuration of the fourth exemplary embodiment of the present invention. Referring to FIG. 8, the fourth embodiment of the present invention includes a moving body (mobile robot) 200 that moves, and a position index 100 that gives information on the relative position of the moving body 200 to the moving body 200. And a correction value calculation necessity notifying means 110 for notifying the moving body 200 that correction value calculation is necessary.

  The moving body 200 includes the same configuration as that of the first embodiment.

  The position index 100 performs the same operation as that in the first embodiment, and has the same input / output as that in the first embodiment.

  The correction value calculation necessity notification means (correction value calculation necessity notification unit) 110 notifies the mobile unit 200 that it is necessary to calculate a correction value.

  The correction value calculation necessity notification means 110 outputs a notification signal to the moving body 200. For example, as a situation where correction value calculation is required, the position of the position index 100 may change. At this time, since the state of the floor may be changed, it is necessary to calculate a correction value. As a method for detecting that the position of the position index 100 has changed, a spring switch or the like is formed on the surface of the position index 100 that is in contact with the floor surface, and when the position index 100 is placed on the floor surface, the spring switch is The possibility that the position has changed may be detected by using the fact that the spring switch is turned off when the position index 100 is turned off and the position index 100 is separated from the floor surface.

  In addition, the ultrasonic wave is emitted from the position index 100 to the floor surface, the position is detected by GPS (Global Positioning System), the camera is mounted on the position index 100, and the surrounding environment is changed by image matching. The possibility that the position has changed may be detected by detecting the above.

  In the correction value calculation necessity notification means 110, as the notification signal, blinking light may be emitted by a light source. Moreover, it is not necessary to have a lighting pattern including blinking, and it may be suitable for the movement notification signal acquisition process in the correction value calculation necessity notification receiving unit 341.

  In addition, the correction value calculation necessity notification means 110 may use a visually captureable index such as a two-dimensional pattern or a visible light source, or a sound source, a radio wave transmission source, a magnetic field generation source, a laser surveying instrument, or the like.

  The index detection unit 210 and the self-position identification unit 220 perform the same operation as in the first embodiment, and have the same input / output as in the first embodiment.

  The correction value calculation necessity judging means 300 receives the notification signal from the correction value calculation necessity notifying means 110 and detects this to determine whether or not the correction value needs to be calculated and whether or not to calculate the correction value. Generates these flags.

  The correction value calculation necessity determination unit 300 receives a notification signal from the correction value calculation necessity notification unit 110. In addition, a flag indicating whether or not to calculate a correction value is output to the correction value calculation unit 230 or the route generation unit 250.

  Referring to FIG. 8, the correction value calculation necessity determination unit 300 receives the correction value calculation necessity notification reception unit 341 that receives the notification signal from the correction value calculation necessity notification unit 110 and the reception information by the correction value calculation necessity notification reception unit 341. And a correction value calculation necessity notification determination unit 342 for detecting a notification signal.

  The correction value calculation necessity notification receiving unit 341 receives a notification signal from the correction value calculation necessity notification means 110.

  The correction value calculation necessity notification reception unit 341 receives the notification signal from the correction value calculation necessity notification unit 110 and outputs the received information to the correction value calculation necessity notification determination unit 342.

  For example, when the correction value calculation necessity notification unit 110 is a light source, a camera is used as the correction value calculation necessity notification reception unit 341, and imaging data of the light source (correction value calculation necessity notification unit 110) is used as the correction value calculation necessity notification determination unit 342. May be output.

  The correction value calculation necessity notification receiving unit 341 is not limited to an imaging device such as a camera, and may be configured to correspond to the notification signal of the correction value calculation necessity notification means 110, such as a microphone, a radio wave receiver, or a magnetic field detector. Of course.

  In addition, if the hardware constituting the index detection unit 210 is shared and used as the configuration of the correction value calculation necessity notification receiving unit 341, the hardware configuration can be simplified.

  The correction value calculation necessity notification determination unit 342 detects a notification signal from the reception result by the correction value calculation necessity notification reception unit 341.

  When a notification signal is detected, the correction value calculation necessity notification determination unit 342 determines that the correction value needs to be calculated, and generates a flag for calculating the correction value. If the notification signal is not detected in the correction value calculation necessity notification determination unit 342, it is determined that there is no need to calculate the correction value, and a flag that does not calculate the correction value is generated.

  More specifically, the correction value calculation necessity notification determination unit 342 receives the reception result from the correction value calculation necessity notification reception unit 341 as an input. If it is determined that the correction value needs to be calculated, a flag for calculating the correction value is output to the correction value calculation means 230. If the correction value cannot be determined to be calculated, A flag that does not calculate the correction value is output to the route generation unit 250.

  For example, assuming that the correction value calculation necessity notification means 110 is a point light source, the notification signal is blinking of the point light source, and the correction value calculation necessity notification reception unit 341 is a camera, first, the correction value calculation necessity notification reception unit 341. Acquires an image of a point light source.

  Then, the correction value calculation necessity notification receiving unit 341 attempts to detect a point light source by performing image processing such as binarization and labeling. When a point light source is detected in the correction value calculation necessity notification receiving unit 341, a flag for calculating a correction value is generated and output to the correction value calculation means 230.

  If the point light source cannot be detected by the correction value calculation necessity notification receiving unit 341, a flag that does not perform correction value generation is generated and output to the route generation unit 250.

  Note that the method of detecting the notification signal in the correction value calculation necessity notification receiving unit 341 may be suitable for the notification signal issued by the correction value calculation necessity notification means 110. For example, when the notification signal is a sound wave, a predetermined sound wave is used. Similarly, in the case of radio waves, radio wave analysis processing may be used, and in the case of magnetic fields, magnetic field change detection processing may be used.

  The correction value calculation unit 230 performs the same operation as that of the first embodiment, and has the same input / output as that of the first embodiment.

  The correction value recording unit 240 is implemented by the storage device of the moving body 200 and records the correction value by the correction value calculation unit 230.

  The correction value recording unit 240 receives the correction value from the correction value calculation unit 230 and outputs the recorded correction value to the route generation unit 250.

  For example, the correction value recording unit 240 may be implemented by a storage device of a remote computer that can communicate with the moving body 200.

  Further, when the installation position of the position index 100 changes, the notification signal pattern of the correction value calculation necessity notification means 110 may also change, and the correction value calculation necessity determination means 300 may detect this change. The correction value recording means 240 may record the notification signal pattern and the correction value calculated at that time as a set. By doing so, an appropriate correction value can be referred to from the notification signal, and the situation where correction value calculation is required can be further reduced.

  The route generation means 250 and the movement means 260 each perform the same operation as in the first embodiment, and have the same input / output as in the first embodiment.

  Next, the overall operation of the present embodiment will be described in detail with reference to the flowchart of FIG.

  Note that the start point D0 of the flowchart includes a state immediately after the moving body 200 has moved by some means (after moving the path corrected by the flowchart or after moving the path for calculating the correction value). ).

  Steps D1 to D3 in FIG. 9 are the same processes as steps A1 to A3 in FIG. 3 showing the overall operation in the first embodiment.

  When a section that requires correction has been reached, the correction value calculation necessity notification determination unit 342 detects the notification signal of the correction value calculation necessity notification means 110 and determines whether or not correction value calculation is necessary ( Step D4).

  If it is determined in step D4 that correction values need to be calculated, steps D5 to D6 are executed. Steps D5 and D6 are the same processes as steps B5 and B6 in FIG. 5 showing the overall operation of the second embodiment. If it cannot be determined in step D4 that a correction value needs to be calculated, step D7 is executed.

  Step D7 is the same process as step C7 in FIG. 7 showing the overall operation of the third embodiment.

  Next, the effect of this embodiment will be described.

  In the present embodiment, the position change of the position index 100 can be explicitly transmitted to the moving body 200. For this reason, the correction value calculation necessity determination means 300 can easily determine whether or not the correction value needs to be calculated as compared with the previous embodiments.

<Fifth embodiment>
Next, a fifth embodiment of the present invention will be described. FIG. 10 is a diagram showing the configuration of the fifth exemplary embodiment of the present invention. Referring to FIG. 10, the fifth embodiment of the present invention includes a moving body 200 that moves, and a position index 100 that gives information on the relative position of the moving body 200 to the moving body 200.

  In addition to the same configuration as that of the first embodiment, the mobile unit 200 includes a determination result notification unit 270 that notifies the user of the determination result by the correction value calculation necessity determination unit 300. Each of these means operates as follows.

  The position index 100, the index detection means 210, and the self-position identification means 220 each perform the same operation as in the first embodiment, and have the same input / output as in the first embodiment.

  The correction value calculation necessity determination means (correction value calculation necessity determination unit) 300 notifies the determination result of whether or not correction value calculation is necessary in addition to the operation and input / output of the first embodiment. Output to means 270.

  The correction value calculation necessity determination unit 300 includes the same configuration as that of the first embodiment.

  Each part of the correction value calculation necessity determination means 300 operates as follows.

  In the correction value calculation necessity determination means 300, the surrounding environment observation unit 311 and the environment information conversion unit 312 perform the same operation as in the first embodiment, and input / output the same as in the first embodiment. Have.

  The environment information comparison unit 313 performs the same operation as that of the first embodiment, has the same input / output as that of the first embodiment, and further determines whether or not correction value calculation is necessary. The result is output to the determination result notifying unit 270. The environment information comparison unit 313 is the same as that in the first embodiment.

  The environment information recording unit 314 performs the same operation as that of the first embodiment, and has the same input / output as that of the first embodiment.

  The determination result notifying unit (determination result notifying unit) 270 notifies the user of the determination result by the correction value calculation necessity determining unit 300.

  The determination result notification means 270 receives the determination result from the correction value calculation necessity determination means 300 as an input, and outputs the notification of the contents of the determination result to the user.

  For example, the synthesized voice device may notify the user of the necessity of calculating the correction value in spoken language. In addition, as a cue indicating that the correction value needs to be calculated, the light source may be turned on or a sound may be notified through a speaker or the like.

  The correction value calculation unit 230, the correction value recording unit 240, the path generation unit 250, and the movement unit 260 each perform the same operation as that of the first embodiment, and the same input / output as that of the first embodiment. have.

  Next, the overall operation of the present embodiment will be described in detail with reference to the flowchart of FIG.

  The starting point E0 of the flowchart includes a state immediately after the moving body 200 has moved by some means (after moving the path corrected by the flowchart or after moving the path for calculating the correction value). ).

  Steps E1 to E6 in FIG. 11 are the same processes as steps A1 to A6 in FIG. 3 showing the overall operation in the first embodiment.

  If there is nothing that can be determined to be the same in step E6, the determination result notifying means 270 informs the user that the correction value needs to be calculated (step E7). Thereafter, the correction value is calculated by the correction value calculation means 230 (step E8), and the calculated correction value is recorded by the correction value recording means 240 (step E9).

  If there is something that can be determined to be the same in step E6, the determination result notifying means 270 informs the user that it is not necessary to perform correction value calculation (step E10). Thereafter, the path generation means 250 performs correction and moves (step E11).

  If it is difficult to determine whether correction value calculation is required by the correction value calculation necessity determination unit 300, the determination result notification unit 270 informs the user that the determination is difficult, and then asks the user. It is good also as a structure to judge. The user's judgment may be received as an input, and whether or not to execute the correction value calculation may be determined according to the user's judgment.

  In addition, after step E10, the movement is not limited to the above-described movement (step E11). For example, when there is no need to calculate a correction value, the movement is performed by, for example, returning along a route that has been taken. Of course, any process suitable for the movement strategy of the body 200 may be executed.

  Furthermore, although the fifth embodiment for notifying the user of the determination result by the correction value calculation necessity determining means 300 has been described as a modification of the first embodiment, this embodiment is referred to as the second embodiment. Of course, the present invention may be applied to three, four embodiments.

  Next, the effect of this embodiment will be described.

  In the present embodiment, the determination result of the necessity for calculating the correction value of the mobile unit 200 is clearly indicated to the user by transmitting the determination result of the correction value calculation by the mobile unit 200 to the outside of the mobile unit 200. Can show. Thereby, an instruction can be appropriately given from the user to the moving body 200.

Next, specific examples will be described.
In this embodiment, an automatic charging system in which a mobile body (mobile robot) autonomously moves to a charging station and performs charging will be described as an example. It is assumed that the installation location of the charging station may change depending on the hand of the person.

  As shown in FIG. 12, the automatic charging system includes a mobile robot 500 that moves by motor-driven wheels, and a charging station 600 that supplies power to the mobile robot.

  The mobile robot 500 includes a camera 501 that images the front and searches for the charging station 600, and a power supply terminal 502 that is installed on the back surface to receive power.

  The charging station 600 includes a power supply terminal 601 that supplies power to the mobile robot 500 and a position index 602 for informing the mobile robot 500 of the position of the charging station 600.

  Next, the operation of the mobile robot 500 in the embodiment will be described in detail with reference to the flowchart of FIG.

  When the battery is exhausted, the mobile robot 500 starts moving toward the charging station 600.

  First, the position index 602 is observed using the camera 501 (step F1).

  Next, self-position identification and path generation are performed using the position index 602, and the mobile robot 500 is repeatedly moved to the vicinity of the entrance of the charging station 600 (step F2).

  As the mobile robot 500 approaches the entrance of the charging station 600, the mobile robot 500 comes into contact with the power supply terminal 502 of the mobile station and the power supply terminal 601 of the charging station 600. Try to rotate.

  Here, since it is necessary to make the power supply terminal 502 of the robot and the power supply terminal 601 of the charging station come into contact with each other, the accuracy of rotation is important. However, unlike the movement in the previous step F2, since the position index 602 exists behind the mobile robot 500, the position index 602 cannot be observed from the mobile robot 500.

  Therefore, it is necessary to ensure the movement accuracy by correcting the rotation amount in advance.

  Therefore, next, it is determined whether or not the calculation of the correction value is invalid.

  First, the surrounding environment of the position index 602 is imaged by the camera 501 (step F3).

  Thereafter, in the same manner, the surrounding environment image captured in the past is compared with the currently captured surrounding environment image to check whether there is any that can be determined to be the same (step F4).

  If there is nothing that can be determined to be the same in step F4, first, a correction value for correcting the rotation amount is obtained (step F5).

Here, a model having a proportional relationship between the instructed rotation angle and the actual rotation angle is used. In other words, when the designated rotation angle is x, the actual rotation angle is y, and the proportionality coefficient is a, it is expressed as Expression (4).
y = ax (4)

Solving equation (4) for x

x = y / a (5)

  Expression (5) is an expression for obtaining the rotation angle y instructed from the actual rotation angle x, in other words, an expression for obtaining the angle x to be instructed from the target rotation angle y.

  That is, if the proportional coefficient a is determined, the rotation amount can be corrected. This proportionality coefficient a functions as a correction coefficient and becomes a “correction value” in the present invention.

  As a specific method for obtaining the correction value, first, the mobile robot 500 makes one rotation on the spot. At this time, the rotation angle instructed to the mobile robot 500 is set to 360 degrees.

Next, after the movement is completed, the actual rotation angle is obtained by observing the position index 602. Assuming that the actual rotation angle is cR, the correction value a can be obtained from Equation (6).

a = cR / 360 (6)

Next, the obtained correction value a is recorded in association with the surrounding environment image (step F6).
.

  Thereafter, the process returns to Step F1.

  If there is anything that can be determined to be the same in step F4, the posture is turned to the charging station 600 using the correction value a associated with the past surrounding environment image determined to be the same (step F7). .

The corrected rotation amount cC instructed to the mobile robot 500 can be obtained by Expression (7), where the rotation amount before correction is cO.

cC = cO / a (7)

  Next, the mobile robot 500 moves backward as it is and docks with the charging station 600. Then, the power supply terminal 502 on the back of the mobile robot 500 is brought into contact with the power supply terminal 601 installed in the charging station 600 to start power supply (step F8).

  Next, the function and effect of this embodiment will be described.

  In this embodiment, it is assumed that the charging station may be moved. Therefore, the mobile robot 500 is moved under a situation where it is not known when the correction value changes. In order to cope with this, when the correction value is calculated every time the route needs to be corrected, it takes a very long time to make one rotation in front of the charging station 600 before docking. End up.

  Furthermore, in this situation, since the remaining battery of the mobile robot 500 is low, it is desirable to be able to dock in as short a time as possible.

  In order to cope with such a situation, the present invention records the correction value in association with the surrounding environment, thereby making it possible to minimize the execution of the calculation of the correction value, while reducing the effort of the user, The mobile robot 500 can be docked with the charging station 600 in a short time.

  INDUSTRIAL APPLICABILITY According to the present invention, the present invention can be applied to uses such as a movement accuracy improving unit for a mobile robot that travels in a general home environment or office environment where a position index is easily concealed by a free route. Moreover, it is applicable also to uses, such as an automatic driving system which puts in a car garage. Furthermore, in the present invention, the moving body is not limited to a mobile robot that autonomously moves to a target point, but can be applied to movement control of an arbitrary robot controlled by remote control or the like. As a moving body, it is also applicable to vehicles (cars, trains) equipped with intelligence such as automatic driving with image recognition function, transport vehicles (carriers) traveling in facilities such as factories, flying bodies, ships, submarines, etc. Of course you can.

  It should be noted that the disclosures of the above patent documents are incorporated herein by reference. Within the scope of the entire disclosure (including claims) of the present invention, the embodiments and examples can be changed and adjusted based on the basic technical concept. Various combinations and selections of various disclosed elements are possible within the scope of the claims of the present invention. That is, the present invention of course includes various variations and modifications that could be made by those skilled in the art according to the entire disclosure including the claims and the technical idea.

Claims (25)

A correction value calculation unit for calculating a correction value used in connection with the movement of the moving object;
A correction value calculation necessity determination unit for determining whether or not the correction value calculation is necessary in the correction value calculation unit;
Including
The correction value calculation necessity determination unit
Comparison of information around the mobile object and its past history information,
A mobile system characterized by autonomously determining whether the correction value needs to be calculated based on internal information of the mobile object or past information of the internal information of the mobile object. When it is determined by the correction value calculation necessity determination unit that calculation of the correction value is unnecessary, the movement of the moving body is corrected based on the correction value recorded in the past,
The mobile system according to claim 1, wherein the correction value calculation unit calculates the correction value when the correction value calculation necessity determination unit determines that the correction value needs to be calculated. The correction value calculation necessity determination unit, when correction of information related to the planned movement of the moving body is performed,
Before calculating the correction value corresponding to the correction by the correction value calculation unit,
A correction value corresponding to the correction is calculated based on at least one of comparison information between past peripheral information acquired by the mobile object and current peripheral information, internal information of the mobile object, and past history information. The mobile system according to claim 1, wherein it is determined whether or not it is necessary to perform the operation. A correction value recording unit for recording the correction value calculated by the correction value calculation unit;
When the correction value calculation necessity determining unit determines that the calculation of the correction value is unnecessary, the correction of movement is performed using the correction value corresponding to the correction already recorded in the correction value recording unit. Is done,
When the correction value calculation necessity determining unit determines that the correction value needs to be calculated, movement correction is performed using the correction value calculated by the correction value calculating unit, and the correction value calculation is performed. 4. The mobile system according to claim 1, wherein the correction value calculated by the unit is recorded in the correction value recording unit as a correction value corresponding to the correction. 5. A correction value calculation unit for calculating a correction value used in connection with the movement of the moving object;
A correction value calculation necessity determination unit for determining whether or not the correction value calculation is necessary in the correction value calculation unit;
With
The correction value calculation necessity determination unit obtains information on the surrounding environment of the moving body, and an ambient environment observation unit,
An environment information recording unit for recording information on the surrounding environment acquired by the surrounding environment observation unit;
An environment information comparison unit that compares information on the surrounding environment acquired by the environment monitoring unit with information on the surrounding environment already recorded in the environment information recording unit;
Including
As a result of the comparison by the environment information comparison unit, when it can be determined that the acquired information on the surrounding environment and the already recorded information on the surrounding environment are the same, the calculation of the correction value is unnecessary. A mobile system characterized in that, when it is determined that the same value cannot be determined, it is determined that a correction value needs to be calculated. A correction value recording unit for recording the correction value calculated by the correction value calculation unit;
When the correction value is stored in the correction value recording unit in association with the surrounding environment information and it is determined that the calculation of the correction value is unnecessary, the acquired ambient environment is obtained from the correction value recording unit. 6. The mobile system according to claim 5, wherein a correction value corresponding to the information is read and correction is performed. A correction value calculation unit for calculating a correction value used in connection with the movement of the moving object;
A correction value calculation necessity determination unit for determining whether or not the correction value calculation is necessary in the correction value calculation unit;
A correction value recording unit for recording the correction value calculated by the correction value calculation unit;
With
The correction value calculation necessity determination unit, a movement result determination unit that determines a movement result of the moving body,
A determination result recording unit that records a determination result of the movement result of the moving body by the movement result determination unit;
A recorded information statistical processing unit that performs predetermined statistical processing using the determination result of the moving result of the moving object recorded in the determination result recording unit and the correction value recorded in the correction value recording unit;
Including
Determining whether the calculation of the correction value is necessary according to whether the result of the statistical processing by the recorded information statistical processing unit satisfies a predetermined criterion. A moving system characterized by. When the recording information statistical processing unit determines that the calculation of the correction value is unnecessary, the correction value calculation unit does not calculate the correction value,
The recorded information statistical processing unit selects and outputs a predetermined correction value among the correction values recorded in the correction value recording unit, or outputs the correction value recorded in the correction value recording unit. The mobile system according to claim 7, wherein the result of the arithmetic processing is output. A correction value calculation unit for calculating a correction value used in connection with the movement of the moving object;
A correction value calculation necessity determination unit for determining whether or not the correction value calculation is necessary in the correction value calculation unit;
A correction value recording unit for recording the correction value calculated by the correction value calculation unit;
With
The correction value calculation necessity determination unit is configured such that a recent correction value and a past correction value recorded in the correction value recording unit in an arbitrary section moved before the section in which the moving body is scheduled to move. Includes a correction value section match determination unit that determines whether or not the same,
If it is determined that the latest correction value and the past correction value are the same as a result of determination by the correction value section coincidence determination unit, it is determined that the calculation of the correction value is unnecessary. And if it cannot be determined that they are the same, it is determined that a correction value needs to be calculated. When the correction value calculation necessity determination unit determines that the calculation of the correction value is unnecessary, the movement information is corrected using the correction value recorded in the correction value recording unit, and A route generation unit for generating a movement route;
A moving unit that moves the moving body according to a moving route by the route generating unit;
The mobile system according to claim 4, comprising:   11. The movement system according to claim 10, wherein the correction value recording unit records a correction value corresponding to a section in which the moving body moves. A correction value calculation unit for calculating a correction value used in connection with the movement of the moving object;
A correction value calculation necessity determination unit for determining whether or not the correction value calculation is necessary in the correction value calculation unit;
A correction value calculation necessity notification unit that is outside the mobile body and notifies the mobile body that it is necessary to calculate a correction value;
Including
The correction value calculation necessity determination unit includes a correction value calculation necessity notification reception unit that receives a notification signal from the correction value calculation necessity notification unit;
From the reception result by the correction value calculation necessary notification receiving unit, a correction value calculation necessary notification unit for determining the presence or absence of a notification signal;
Including
As a result of determining the presence or absence of a notification signal by the correction value calculation necessary notification unit, if there is a notification signal, it is determined that calculation of a correction value is necessary,
A mobile system characterized in that, when there is no notification signal, it is determined that calculation of a correction value is unnecessary.   The mobile system according to claim 1, further comprising a determination result notifying unit that notifies a user of a determination result by the correction value calculation necessity determining unit.   The mobile robot which comprises the said mobile body of the movement system of any one of Claims 1 thru | or 12 and 14. Including a control step of controlling movement by correcting information relating to movement of the computer-controlled moving body,
The control step is
A correction value calculating step for calculating a correction value used in connection with the movement of the moving body;
A correction value calculation necessity determination step for determining whether or not the correction value calculation is necessary in the correction value calculation step;
Including
The correction value calculation necessity determination step includes:
Comparison of information around the mobile object and its past history information,
A movement control method characterized by autonomously determining whether the correction value needs to be calculated based on internal information of the mobile object or past information of the internal information of the mobile object. Including a control step of controlling movement by correcting information relating to movement of the computer-controlled moving body,
The control step is
A correction value calculating step for calculating a correction value used in connection with the movement of the moving body;
A correction value calculation necessity determination step for determining whether or not the correction value calculation is necessary in the correction value calculation step;
Including
When the mobile object detects a position index, it obtains position information based on the position index, and if correction of the direction or route of the mobile object is necessary in relation to the position information, whether or not a correction value needs to be calculated To determine
Including a determination step of acquiring information on the surrounding environment of the mobile body, and determining a similarity between the information on the surrounding environment and information on the surrounding environment recorded in advance in a storage unit,
In the correction value calculation necessity determination step, if there is one that can be determined to be the same as a result of the determination in the determination step, it is determined that calculation of the correction value is unnecessary, and if there is no one that can be determined to be the same, It is determined that calculation of the correction value is necessary,
When calculation of the correction value is not necessary, using the calculated correction value recorded in the storage unit, performing the movement using the position information and the information regarding movement corrected using the correction value,
When calculation of the correction value is necessary, in the correction value calculation step, the correction value is calculated, and the movement is performed using the position information and the information regarding the movement corrected using the calculated correction value. Recording the calculated correction value in the storage unit;
The movement control method characterized by the above-mentioned. In order to determine whether the correction value needs to be calculated, instead of the determination step,
18. The movement control method according to claim 17, wherein whether or not a correction value needs to be calculated is determined based on determination result information on the success or failure of movement performed by the mobile body and the correction value. In order to determine whether the correction value needs to be calculated, instead of the determination step,
In a section in which the mobile body has moved before a section that is scheduled to move, the latest correction value recorded in the storage unit is compared with a past correction value to determine whether or not a correction value needs to be calculated. To
The movement control method according to claim 17. In order to determine whether the correction value needs to be calculated, instead of the determination step,
Detecting a notification signal to be notified to the moving body from the outside, and determining whether a correction value needs to be calculated;
The movement control method according to claim 17. A program for causing a computer to execute processing for controlling movement by correcting information relating to movement of a computer-controlled moving body,
A correction value calculation process for calculating a correction value used in connection with the movement of the moving body;
A correction value calculation necessity determination process for determining whether or not the correction value needs to be calculated in the correction value calculation process;
Including
As the correction value calculation necessity determination process,
Comparison of information around the mobile object and its past history information,
Based on the internal information of the mobile object or the past information of the internal information of the mobile object, a process for autonomously determining whether the correction value needs to be calculated,
A program to be executed by the computer. A program for causing a computer to execute processing for controlling movement by correcting information relating to movement of a computer-controlled moving body,
A correction value calculation process for calculating a correction value used in connection with the movement of the moving body;
A correction value calculation necessity determination process for determining whether or not the correction value needs to be calculated in the correction value calculation process;
When a position index is detected, a process for obtaining position information based on the position index;
When it is necessary to correct the direction and path of the moving body in relation to the position information, in order to determine whether or not a correction value needs to be calculated,
Processing for obtaining information on the surrounding environment of the mobile body and determining the similarity between the information on the surrounding environment and information on the surrounding environment recorded in advance in a storage unit;
In the correction value calculation necessity determination process, if there is one that can be determined to be the same as a result of the determination of the similarity, it is determined that calculation of the correction value is unnecessary, and if there is no one that can be determined to be the same, correction is performed. Processing to determine that the calculation of the value is necessary,
When the calculation of the correction value is unnecessary, the information on the movement corrected using the position information and the calculated correction value recorded in the storage unit is output to the moving means and the movement is performed.
When calculation of a correction value is necessary, the correction value is calculated in the correction value calculation process, and the position information and the information related to movement corrected using the calculated correction value are output to the moving means. And a process of recording the calculated correction value in the storage unit,
A program for causing the computer to execute. The program according to claim 22, wherein
In order to determine whether the correction value needs to be calculated, instead of the determination process,
The program which makes the said computer perform the process which judges the necessity of calculation of a correction value based on the determination result information regarding the success or failure of the movement which the said mobile body performed, and the said correction value. The program according to claim 22, wherein
In order to determine whether the correction value needs to be calculated, instead of the determination process,
In a section in which the mobile body has moved before a section that is scheduled to move, the latest correction value recorded in the storage unit is compared with a past correction value to determine whether or not a correction value needs to be calculated. A program that causes the computer to execute processing to be performed. The program according to claim 22, wherein
In order to determine whether or not the correction value needs to be calculated, instead of the determination process,
A program for causing the computer to execute a process of detecting a notification signal notified to a moving body from the outside and determining whether a correction value needs to be calculated. When the correction value calculation necessity determining unit determines that the calculation of the correction value is unnecessary, the correction of movement is performed using the correction value corresponding to the correction already recorded in the correction value recording unit. Is done,
When the correction value calculation necessity determining unit determines that the correction value needs to be calculated, movement correction is performed using the correction value calculated by the correction value calculating unit, and the correction value calculation is performed. The movement system according to claim 5, wherein the correction value calculated by the unit is recorded in the correction value recording unit as a correction value corresponding to the correction.

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