JP6857701B2 - Work equipment, display devices and display systems for remote control of work equipment - Google Patents

Description

The present invention relates to a work machine, a display device, and a display system that displays an image sent from the work machine for remote control of the work machine.

As a display system that displays images sent from the work machine to remotely control the work machine, a camera is installed in the work machine that is remotely controlled at a place away from the work site where the work machine works, and the camera is used. A display system that transmits a captured image (moving image) to a remote control side by wireless communication and displays the obtained image on a display device on the remote control side in real time has been conventionally known.

For example, Patent Document 1 discloses a display system that displays a panoramic image of the surrounding situation of a working machine on a display device in real time.

Further, Patent Document 2 is a display system that displays an image of a work site on a display device in real time based on data transmitted from a camera mounted on a construction machine by 2.4 GHz low power wireless communication due to the restrictions of the Radio Law. Is disclosed.
Japanese Unexamined Patent Publication No. 2008-11169 JP-A-2002-345058

By the way, in a display system for remote control of a work machine, it is desired to make a display image displayed on the display device follow the movement of the operator's line of sight from the viewpoint of improving the operability of remote control.

However, Patent Document 1 merely discloses a display system that switches a panoramic image according to an operation of a switching pedal, and does not have a configuration in which a display image displayed on a display device follows the movement of the operator's line of sight. Therefore, it cannot be said that the operation feeling is good. Further, Patent Document 2 does not disclose a display system for making a display image displayed on a display device follow the movement of the operator's line of sight.

The following patent documents can be mentioned as techniques related to the present invention, but in any case, they do not constitute the present invention.
U.S. Patent No. 6795109 U.S. Patent No. 8274550 U.S. Patent No. 6195204 U.S. Patent Application Publication No. 2006/01037223 U.S. Patent Application Publication No. 2007/0182812 U.S. Patent No. 8355041

Therefore, the present invention is a display system for remote operation of a work machine, a display device, and the work machine, and the work machine capable of following the movement of the operator's line of sight with the display image displayed on the display device . It is an object of the present invention to provide a display device and a display system.

In order to solve the above problems, the present invention provides the following first and second aspects of the working machine, the display device, and the display system for remote control of the first to third aspects of the working machine.

(1) Working machine
(1-1) Working machine of the first aspect
A camera unit, before subjected to cut processing to cut a predetermined cut angle corresponding to the viewing angle of the operator shadow image shooting taken by hear camera unit, the head of the pre-Symbol operator received from the external device or in accordance with the movement of the eyeball, the adjustment process of the cut angle adjustment of the photographing field image and the row cormorant image processing apparatus, a working machine wherein the image processing apparatus, prior Symbol operator working machine moving Kino response speed of the head or eye is characterized by performing the adjustment processing or the cut processing is delayed the response speed is faster than a predetermined response time.

(1-2) Working machine of the second aspect
A camera unit, before subjected to cut that cut processing at a predetermined cut angle corresponding to the viewing angle of the operator shadow image shooting taken by hear camera unit, the head of the pre-Symbol operator received from the external device in accordance with the movement of the part or the eye, the adjustment process of the cut angle adjustment of the photographing field image and the row cormorant image processing apparatus, a working machine provided with a front asked camera unit, the camera unit working machine of lens is characterized in that the work skill of the working machine is provided at a height position you corresponding to eyes height at if sitting on the seat's seat.

(2) Display device The photographed image received from the image processing device that crops the captured image captured by the camera unit provided in the work machine at a predetermined cropping angle corresponding to the viewing angle of the operator is displayed, and the operator A display device for remote operation of a working machine that detects the movement of the head or eyeball of an operator and transmits the detected movement of the head or eyeball of the operator to the image processing device. the work auxiliary information corresponding to the captured image is displayed in association with the captured image with the captured image, the work auxiliary information is remote work machine, wherein actuation range der Rukoto of the working machine Display device for operation.

(3) Display system
(3-1) In the display system for the remote operation of the display system working machine of the first aspect, a camera unit provided on the working machine, manipulate the shadow image shooting captured by the camera unit and line cormorant image processing apparatus cut processing to cut a predetermined cut angle corresponding to the viewing angle of the person, before Symbol to display the camera image transmitted from the image processing apparatus, a head or eye movement of the operator and a display device to send before Symbol image processing apparatus detects, before Symbol image processing apparatus, according to the head or eye movements of the display device the operator sent from the display device performs adjustment processing of the cut angle adjustment of the photographing field image to be transmitted to, delaying the response speed is faster than the response speed is predetermined response speed of the operator's head or eye movement A display system for remote operation of a working machine, which comprises performing the adjustment process or the cutting process.

(3-2) Display system of the second aspect A display system for remote operation of a work machine, in which an operator visually recognizes a camera unit provided in the work machine and a photographed image taken by the camera unit. An image processing device that performs cutting processing at a predetermined cutting angle corresponding to an angle and the captured image transmitted from the image processing device are displayed, and the movement of the operator's head or eyeball is detected and the image processing is performed. The image processing device includes a display device to be transmitted to the device, and the image processing device is the image of the captured image to be transmitted to the display device in response to the movement of the operator's head or eyeball sent from the display device. adjust the cut angle, the display device, the work auxiliary information corresponding to the captured image is displayed in association with the captured image with the captured image, the work auxiliary information, in operation range of the previous SL working machine A display system for remote control of work equipment, which is characterized by being present.

(3-3) In the display system for the remote operation of the display system working machine of the third aspect, a camera unit provided on the working machine, manipulate the shadow image shooting captured by the camera unit an image processing apparatus that performs cut processing that cut at a predetermined cut angle corresponding to the viewing angle of the person, before Symbol to display the camera image transmitted from the image processing apparatus, a head or eye movement of the operator and a display device to send before Symbol image processing apparatus detects, before Symbol image processing apparatus, according to the head or eye movements of the display device the operator sent from the display device the cut angle of the imaging field image to be transmitted to adjust the front asked camera unit, Looking height at If lens of the camera unit is created skill of the working machine is seated on the seat's seat display system for the remote operation of the working machine, characterized in that provided in the corresponding to that height.

According to the present invention, the work machine, the display device, and the display system for remote control of the work machine, and the work machine and the display capable of following the movement of the line of sight of the operator with the display image displayed on the display device. Devices and display systems can be provided.

FIG. 1 is a schematic configuration diagram schematically showing a display system for remote control of a working machine according to the first embodiment. FIG. 2 is a perspective view showing a schematic configuration of a support body in a support member provided in the work machine shown in FIG. 1 and a plurality of camera units supported by the support body. FIG. 3 is a block diagram showing a system configuration of an image processing device on the work equipment side in the display system according to the first embodiment. FIG. 4 is an explanatory diagram for explaining a cutting process for cutting a part of a panoramic image by an image processing device. FIG. 5 is a block diagram showing a system configuration of a remote control device on the remote control side in the display system according to the first embodiment. FIG. 6 is an explanatory diagram for explaining an adjustment process for adjusting a part of the panoramic image according to the movement of the operator's head by the image processing device. FIG. 7 is a flowchart showing an example of the control operation of the display system according to the first embodiment. FIG. 8 is a schematic configuration diagram schematically showing a display system for remote control of the work machine according to the second embodiment. FIG. 9 is a block diagram showing a system configuration of an image processing device on the working machine side in the display system for remote control of the working machine according to the third embodiment. FIG. 10 is a block diagram showing a system configuration of a remote control device on the remote control side in the display system according to the third embodiment. FIG. 11 is a flowchart showing an example of the control operation of the display system according to the third embodiment. FIG. 12 is a schematic configuration diagram schematically showing a display system for remote control of the working machine according to the fourth embodiment. FIG. 13 is a schematic configuration diagram schematically showing a display system for remote control of the working machine according to the fifth embodiment. FIG. 14 is a schematic configuration diagram of a pair of cameras constituting the camera unit in the display system for remote control of the work machine according to the sixth embodiment and an example of a lighting device provided on the pair of cameras as viewed from the front. is there. FIG. 15 shows a part of the work assistance information corresponding to a part of the panoramic image corresponding to a part of the panoramic image together with a part of the panoramic image in the display system for remote control of the work machine according to the seventh embodiment. It is a display figure which shows an example of the display screen which is additionally displayed on the display device.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

(First Embodiment)
FIG. 1 is a schematic configuration diagram schematically showing a display system 100 for remote control of the work machine 200 according to the first embodiment.

As shown in FIG. 1, in the display system 100 for remote control of the work machine 200, the camera units 310 to 310 are provided in the work machine 200 which is remotely controlled at a place away from the work site where the work machine 200 works. The image (moving image) taken by the camera units 310 to 310 is transmitted to the remote control side 120 by wireless communication, and the obtained image is displayed in real time on the display device 410 of the remote control side 120. ..

In the display system 100, the work machine 200 is an unmanned work machine, and the operator 500 who remotely controls the work machine 200 at a place away from the work site checks the display screen of the display device 410 while checking the display screen of the display device 410 on the remote control side 120. It is configured to be operated remotely by sending an operation command from. As a result, the work machine 200 can work at a dangerous work site (for example, a contaminated work site) where humans cannot enter.

The work machine 200 has a work unit 220 that can be swiveled in the horizontal direction and swings in the vertical direction. In this example, the work machine 200 is a construction work machine (specifically, an excavator car). The work machine 200 has a traveling body 210 constituting a crawler, and the working unit 220 is provided so as to be able to turn in the horizontal direction (around the axis along the vertical direction) with respect to the traveling body 210. The working unit 220 includes an upper body 221 that can turn horizontally with respect to the traveling body 210, a boom 222 that can swing vertically with respect to the upper body 221 (around the axis along the horizontal direction), and a boom. It has an arm 223 that can swing in the direction perpendicular to 222, and a bucket 224 that can swing in the direction perpendicular to the arm 223. Here, the "horizontal direction" and the "vertical direction" are the directions when the working machine 200 is installed on a horizontal plane.

In this example, the attachment attached to the tip of the arm 223 is a bucket 224, but the attachment is not limited to this, and the tip of the arm 223 is appropriately replaced with an attachment according to the work content. can do.

Further, the work machine 200 is not limited to the excavator car in this example, and may be another construction work machine or an agricultural work machine.

The working machine 200 further includes a remote control device 230. The remote control device 230 remotely controls the main body of the work machine 200, and is configured to perform wireless communication with the main body of the work machine 200. The remote control device 230 receives an operation by the operator 500 and transmits an operation command based on the received operation to the work machine 200 main body by wireless communication. The remote control device 230 includes an operation unit 231 such as an operation lever for operating the work unit 220 (specifically, constituent members such as the upper body 221 and the boom 222, the arm 223 and the bucket 224).

The display system 100 is composed of a component 300 on the working machine side 110 and a component 400 on the remote control side 120.

The component 300 of the work machine side 110 includes a plurality of camera units 310 to 310 and an image processing device 320 provided in the work machine 200. The component 400 of the remote control side 120 includes a display device 410 and a remote control device 420.

The component 300 of the work machine side 110 further includes a support member 330. The lower end of the support member 330 is supported (fixed in this example) by the upper body 221 of the working unit 220 of the working machine 200, while the upper end portion of the plurality of camera units 310 to 310 is supported by the plurality of camera units 310. ~ 310 is supported (fixed in this example) so as to be in a horizontal posture. Here, the horizontal posture is a posture when the work machine 200 is installed on a horizontal surface.

The support member 330 supports a support 331 that supports a plurality of camera units 310 to 310, and a support base that supports the support 331 at the upper end and is supported by the upper body 221 at the lower end (support 332 in this example). And have.

FIG. 2 is a perspective view showing a schematic configuration of a support body 331 in a support member 330 provided in the work machine 200 shown in FIG. 1 and a plurality of camera units 310 to 310 supported by the support body 331. Note that FIG. 2 shows a state in which a part of the plurality of (five in this example) camera units 310 to 310 provided on the support 331 is removed from the support 331, and actually, the plurality (this). All of the camera units 310 to 310 (five in the example) are provided on the support 331.

As shown in FIG. 2, each of the plurality of camera units 310 to 310 includes a pair of cameras for the left eye and a pair of cameras for the right eye, 311, 312. Specifically, the pair of cameras 311, 312 is composed of a left-eye camera 311 corresponding to the left eye of the operator 500 and a right-eye camera 312 corresponding to the right eye of the operator 500. In the pair of cameras 311, 312, the distance d between the center positions of the lenses is the same as the distance between the center positions of the average human pupil. In this example, the pair of cameras 311, 312 constituting the plurality of camera units 310 to 310 are all small digital video cameras of the same type.

The support 331 supports the plurality of camera units 310 to 310 in all directions or substantially omnidirectionally so that the captured images captured by the plurality of camera units 310 to 310 overlap at a predetermined shooting area ratio. It is composed. Specifically, the support 331 has a plurality of cameras for the left eye, 313-111, so that the captured images for the left eye captured by the plurality of cameras for the left eye, 331 to 111, overlap at a predetermined imaging area ratio. Is omnidirectionally or substantially omnidirectionally supported, and multiple cameras for the right eye are used so that the captured images for the right eye captured by the plurality of cameras 312 to 312 for the right eye overlap at a predetermined imaging area ratio. The cameras 312 to 312 are omnidirectionally or substantially omnidirectionally supported.

Specifically, when there are two camera units 310, the support 331 can be provided with two camera units 310 and 310 at positions facing each other at a predetermined distance, and there are three camera units 310. In the above case, three or more camera units 310 to 310 can be provided at positions radially and evenly or substantially evenly on a virtual circle having a predetermined radius.

Specifically, the support 331 has a plate shape and has a shape having a number of sides corresponding to the number of camera units 310. For example, when there are two camera units 310, the support 331 can be long and long in the direction in which the camera units 310 and 310 are arranged side by side in a plan view, and when there are three or more support bodies 331. Is a regular polygonal shape having the same number of sides as the number of camera units 310-310 and having sides of the same distance (specifically, the three camera units 310-310 have a regular triangular shape in a plan view, and the four camera units 310-310 have a regular polygonal shape. It can be a square shape in a plan view, and a regular pentagon shape in a plan view of the five camera units 310 to 310, ...). Further, the support 331 may have a circular shape in a plan view.

In this example, the number of camera units 310 to 310 is five (that is, the total number of cameras 311, 312 constituting the camera units 310 to 310 is ten) with respect to the pentagonal support 331 in a plan view. The support 331 is fixed radially and evenly or substantially evenly (center position of each side) on a virtual circle having a predetermined radius via a fixing member 331a.

In this way, the support 331 supports the plurality of camera units 310 to 310 at opposite positions or radially and evenly or substantially evenly, so that the plurality of camera units 310 to 310 as a whole have 360 ° in the horizontal direction. Can cover the field of view. The angles of view of the pair of cameras 311, 312 constituting the camera units 310 to 310 can be appropriately determined depending on the arrangement position of the camera units 310. In this example, the vertical angle of view of the pair of cameras 311, 312 is 140 ° (specifically, an angle of 70 ° above and below the virtual horizontal plane).

The plurality of camera units 310 to 310 (see FIG. 1) are seats to be provided in the work machine 200 (in this example, the worker sits when the work machine 200 is assumed to be a manned work machine). The seat) is provided at an arrangement position corresponding to the position in the horizontal direction (specifically, both the front-rear direction and the left-right direction). Further, the plurality of camera units 310 to 310 are workers (for example, height and sitting height) whose central position of the lens in the camera unit 310 has an average physique (for example, height and sitting height) of the destination of the work machine 200 (for example, Western specifications and Asian specifications). For example, it is provided at a seating height position corresponding to the line-of-sight height when it is assumed that a Westerner or an Asian worker) is seated in a seat to be provided in the work machine 200.

In this example, since the boom 222 is provided at the center of the upper body 221 in the left-right direction toward the traveling direction, the support member 330 is on one side in the left-right direction on the front side of the upper body 221. It is erected (on the left side in the example of FIG. 1).

Further, the support member 330 has the center position of the lens in the plurality of camera units 310 to 310 at a height position corresponding to the line-of-sight height when the operator is assumed to be seated on the seat to be provided in the work machine 200. A plurality of camera units 310 to 310 are supported so as to be positioned.

In this example, the image processing device 320 is provided in the working unit 220 of the working machine 200. However, the present invention is not limited to this, and the image processing device 320 may be provided on the support member 330 or the traveling body 210.

The image processing device 320 generates a panoramic image (panoramic moving image data) based on a plurality of captured images (moving image data) taken by the plurality of camera units 310 to 310, and cuts out a part of the generated panoramic image. , A part of the cut panoramic image is transmitted by wireless communication. In this example, the image processing device 320 is composed of a computer (specifically, a personal computer).

FIG. 3 is a block diagram showing a system configuration of an image processing device 320 on the work equipment side 110 in the display system 100 according to the first embodiment.

As shown in FIG. 3, the image processing device 320 includes a control unit 321 that executes processing such as various programs and various arithmetic processing, and a storage unit 322 that stores various data.

The image processing device 320 has a predetermined communication interface for communicating with the plurality of camera units 310 to 310, and is electrically connected to the plurality of camera units 310 to 310 via the connection cable CB1 for the communication interface. It is designed to be connected to. As a result, the image processing device 320 can receive a plurality of captured images IM to IM and IM to IM (moving image data) captured by the plurality of camera units 310 to 310.

In this example, the communication interface between the plurality of camera units 310 to 310 and the image processing device 320 is a universal serial bus (USB: Universal Serial Bus) interface (specifically, an interface compatible with the USB3.0 standard). ing. The communication interface between the plurality of camera units 310 to 310 and the image processing device 320 is not limited to the USB interface, and may be any other communication interface. Further, the communication between the plurality of camera units 310 to 310 and the image processing device 320 is not limited to the wired communication, and may be a short-range wireless communication.

The storage unit 322 includes a volatile memory such as a RAM (Random Access Memory) and a non-volatile memory such as a hard disk device and a flash memory. The volatile memory is appropriately used as a work memory or the like when the control unit 321 executes various processes such as arithmetic processing. Software including programs from external resources (for example, a recording medium or a server on the Internet) is stored (installed) in the non-volatile memory in advance.

Further, the image processing device 320 further includes a communication unit 323 that performs wireless communication (short-range wireless communication in this example) with the communication unit 423 of the remote control device 420 on the remote control side 120.

Here, as the short-range wireless communication, a wireless communication that communicates over a short distance of about several meters to 100 meters can be exemplified. For example, a wireless LAN (Local Area) that communicates at a short distance of about several tens of meters to 100 meters. Examples thereof include (Network) communication and wireless PAN (Personal Area Network) communication that communicates over a short distance of several meters to several tens of meters.

Examples of the wireless LAN communication include wireless LAN communication of the IEEE802.11 standard. Examples of the wireless PAN communication include wireless PAN communication of the IEEE802.15 standard.

The communication unit 323 transmits / receives data to / from the communication unit 423 of the remote control device 420 by using short-range wireless communication. In this example, the wireless LAN communication of the IEEE802.11 standard is performed. It has become.

The communication between the image processing device 320 and the remote control device 420 is not limited to short-range wireless communication, and may be long-range wireless communication exceeding about 100 m.

The image processing device 320 is a captured image IM to IM (moving image) for the left eye and a captured image IM for the right eye, respectively, taken by a pair of cameras 311 to 311 and 312 to 312 constituting the plurality of camera units 310 to 310. The configuration is such that a panoramic image PI (panoramic moving image) for the left eye and a panoramic image PI (panoramic moving image) for the right eye are generated based on ~ IM (moving image).

In the method of generating a panoramic image, for example, in the case of a panoramic image PI for the left eye, a plurality of cameras for the left eye 31 to 311 arranged omnidirectionally or substantially omnidirectionally so that the captured images IM to IM overlap. A panoramic image PI (panoramic moving image) for the left eye is generated by synthesizing a common image in which the plurality of captured images IM to IM, which are overlapped with each other, are combined frame by frame. Similarly, in the case of the panoramic image PI for the right eye, the images for the right eye are taken by a plurality of cameras 312 to 312 for the right eye, which are arranged omnidirectionally or substantially omnidirectionally so that the captured images IM to IM overlap. A panoramic image PI (panoramic moving image) for the right eye is generated by synthesizing the overlapping common images of the plurality of captured images IM to IM for each frame. As a method for generating the panoramic image PI, a conventionally known method can be used, and detailed description thereof will be omitted here.

The image processing device 320 temporarily stores the generated panoramic image PI for the left eye and the panoramic image PI for the right eye in the storage unit 322.

The image processing device 320 is configured to perform a cutting process for cutting out a part PIP of the panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye stored in the storage unit 322.

FIG. 4 is an explanatory diagram for explaining a cutting process for cutting out a part of the panoramic image PI and PI PIP and PIP by the image processing device 320. Since the panoramic image PI for the left eye and the panoramic image PI for the right eye have substantially the same configuration, FIG. 4 shows the panoramic image PI for the left eye and the panoramic image PI for the right eye in one figure. The cutting process will be described collectively.

As shown in FIG. 4, the cutting process for cutting out a part of the panoramic image PI and PI by the image processing device 320 is omnidirectional or substantially omnidirectional (in this example, substantially omnidirectional). , By arranging the head 510 of the operator 500 at the center of the hollow sphere constituting the PI, it becomes easy to understand.

The image processing device 320 operates the panoramic images PI and PI with reference to a predetermined reference point α (for example, a yawing reference angle φy in front of the working machine 200, a rolling reference angle φr, and a pitching reference angle φp). A part of PIP and PIP is cut out at a predetermined cutting angle (β, γ) corresponding to the viewing angle of the person 500. The cutting angles (β, γ) are preset (stored) in the storage unit 322.

As the predetermined reference point α, for example, when one of the plurality of camera units 310 to 310 is provided so as to be located at the front position of the work machine 200, the camera unit at the front position of the work machine 200 is provided. The central pixel in the entire pixel area of the image sent from 310 can be mentioned. Further, the predetermined cutting angle (β, γ) can be an angle corresponding to an angle equal to or less than the viewing angle of an average person. For example, the cutting angle β in the horizontal direction is about 200 ° or less in the vertical direction. The cutting angle γ of the above can be about 125 ° (specifically, 75 ° below and 50 ° above with respect to the virtual horizontal plane) or less.

The image processing device 320 (see FIG. 3) remotely controls a part PIP of the cut panoramic image PI (panoramic moving image data) for the left eye and a part PIP of the panoramic image PI (panoramic moving image data) for the right eye. It is configured to transmit data to each of the 120 remote control devices 420 by wireless communication. Specifically, the image processing device 320 compresses the cut panoramic images PI and some PIPs of the PIs and transmits them to the remote control device 420 in real time by wireless communication. In this example, the data transmitted by wireless communication is assumed to be encrypted data.

The remote control device 420 of the remote control side 120 receives a part PIP of the panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye sent from the image processing device 320, respectively, and receives the received PIP for the left eye. A part PIP of the panoramic image PI and a part PIP of the panoramic image PI for the right eye are transmitted to the display device 410, respectively. The remote control device 420 is composed of a computer (tablet computer in this example) in this example.

FIG. 5 is a block diagram showing a system configuration of a remote control device 420 on the remote control side 120 in the display system 100 according to the first embodiment.

As shown in FIG. 5, the remote control device 420 includes a control unit 421 that executes processes such as various programs and various arithmetic processes, and a storage unit 422 that stores various data.

The remote control device 420 has a predetermined communication interface that communicates with the display device 410, and is electrically connected to the display device 410 via the connection cable CB2 for the communication interface. There is. As a result, the remote control device 420 can transmit a part PIP of the panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye to the display device 410, respectively.

The communication interface between the remote control device 420 and the display device 410 is, in this example, a high-definition multimedia interface [HDMI®: High-Definition Multimedia Interface]. The communication interface between the remote control device 420 and the display device 410 is not limited to HDMI (registered trademark), and may be any other communication interface. Further, the communication between the remote control device 420 and the display device 410 is not limited to the wired communication, and may be a short-range wireless communication.

The storage unit 422 includes a volatile memory such as RAM and a non-volatile memory such as a flash memory. The volatile memory is appropriately used as a work memory or the like when the control unit 421 executes various processes such as arithmetic processing. Software including programs from external resources (for example, a recording medium or a server on the Internet) is stored (installed) in the non-volatile memory in advance.

Further, the remote control device 420 further includes a communication unit 423 that performs wireless communication (short-range wireless communication in this example) with the communication unit 323 of the image processing device 320 on the work equipment side 110.

The wireless communication by the communication unit 423 in the remote control device 420 is the same communication as the wireless communication by the communication unit 323 in the image processing device 320, and description thereof will be omitted here.

In this example, the remote control device 420 is a tablet computer, but in addition to this, for example, a notebook computer, a multifunctional mobile phone (so-called smartphone), a wristwatch type terminal device, and a terminal that can be worn on clothes. It may be a portable terminal device such as a device. The remote control device 420 may be provided on the display device 410. Further, the remote control device 420 is not limited to a portable terminal device, and may be a desktop computer. Further, the operator 500 may remotely control the working machine 200 while standing, or may remotely control the working machine 200 while sitting.

Specifically, the remote control device 420 has a configuration in which a part PIP of the received panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye are temporarily stored in the storage unit 422 and transmitted to the display device 410, respectively. Has been done.

The display device 410 of the remote control side 120 is configured to display while receiving a part PIP of the panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye sent from the remote control device 420, respectively. ing. Specifically, the display device 410 is a partial PIP of the panoramic image PI (panoramic moving image) for the left eye and a partial PIP of the panoramic image PI (panoramic moving image) for the right eye sent from the remote control device 420 in real time. It is designed to perform streaming playback that plays (displays) while receiving.

As a result, the display device 410 can realize a real-time (live) and three-dimensional visual field display (so-called 3D image). As a method for realizing a three-dimensional field of view display by the display device 410, a conventionally known method can be used, and detailed description thereof will be omitted here.

In this example, the display device 410 (see FIG. 1) is configured to be attached to the head 510 (specifically, the eye portion) of the operator 500. Specifically, the display device 410 is a head-mounted display device (HMD: Head Mounted Display). The display device 410 is not limited to the head-mounted display device (HMD), and may be a desktop display device (monitor) or a video projector.

The component 400 of the remote control side 120 further includes a line-of-sight detection unit 411 (see FIGS. 1 and 5) that detects the movement of the line of sight of the operator 500. In this example, the line-of-sight detection unit 411 is a posture detection unit that detects the posture of the head 510 of the operator 500 (see FIG. 1).

As shown in FIG. 1, the line-of-sight detection unit 411 is attached to the head 510 of the operator 500, and the operator is based on the reference posture of the head 510 (for example, the posture in which the operator 500 looks in the horizontal direction). Yawing angle θy around the axis y along the vertical direction of the head 510 of the 500, rolling angle θr around the axis r along the anteroposterior direction, and pitching around the axis p along the left-right direction. ) The angle θp can be detected. The reference value of the reference posture can be set in advance prior to detecting the head 510 of the operator 500.

When the line-of-sight detection unit 411 is a posture detection unit as in this example, various sensors such as a three-dimensional gyro sensor, a three-dimensional gravitational acceleration sensor, a rotary encoder, and a potentiometer can be used. As the line-of-sight detection unit 411, a conventionally known one can be used, and detailed description thereof will be omitted here.

Further, the line-of-sight detection unit 411 (see FIG. 5) provides data on the detected movement of the head 510 of the operator 500 (specifically, the yawing angle θy, the rolling angle θr, and the pitching angle θp with respect to the reference posture of the head 510). Is to be transmitted to the remote control device 420.

In the present embodiment, the line-of-sight detection unit 411 is provided in the display device 410. That is, the display device 410 includes a line-of-sight detection unit 411, and the line-of-sight detection unit 411 moves the head 510 of the operator 500 (specifically, the yawing angle θy, the rolling angle θr, and the pitching angle with respect to the reference posture of the head 510. θp) is detected, and the data of the movement of the head 510 of the operator 500 detected by the line-of-sight detection unit 411 (specifically, the yawing angle θy, the rolling angle θr, and the pitching angle θp with respect to the reference posture of the head 510) is obtained. It is designed to transmit to the remote control device 420.

The transmission of the movement of the head 510 of the operator 500 from the line-of-sight detection unit 411 (display device 410 in this example) to the remote control device 420 is the same as the communication between the remote control device 420 and the display device 410. can do. Further, the transmission of the movement of the head 510 of the operator 500 from the line-of-sight detection unit 411 (display device 410 in this example) to the remote control device 420 is not limited to wired communication, but is short-range wireless communication. You may.

The remote control device 420 is the movement of the head 510 of the operator 500 (specifically, the yawing angle θy and the rolling angle with respect to the reference posture of the head 510) sent from the line-of-sight detection unit 411 (display device 410 in this example). The data of θr and the pitching angle θp) are transmitted to the image processing device 320 of the working machine side 110 by wireless communication.

The image processing device 320 on the work equipment side 110 moves the head 510 of the operator 500 sent from the remote control device 420 (specifically, the yawing angle θy, the rolling angle θr, and the pitching with respect to the reference posture of the head 510. The display device receives the data of the angle θp) and responds to the movement of the head 510 of the operator 500 (specifically, the yawing angle θy, the rolling angle θr, and the pitching angle θp with respect to the reference posture of the head 510). A part of the panoramic image PI for the left eye and a part of the PIP of the panoramic image PI for the right eye to be transmitted to the 410 are adjusted respectively.

FIG. 6 is an explanatory diagram for explaining an adjustment process for adjusting a part of the panoramic image PI, PI, PIP, PIP according to the movement of the head 510 of the operator 500 by the image processing device 320. Since the panoramic image PI for the left eye and the panoramic image PI for the right eye have substantially the same configuration, FIG. 6 shows the panoramic image PI for the left eye and the panoramic image PI for the right eye in one figure. These adjustment processes will be described together.

As shown in FIG. 6, the adjustment process of adjusting the panoramic image PI, a part of the panoramic image PI, PIP, PIP according to the movement of the head 510 of the operator 500 by the image processing device 320 is omnidirectional or substantially omnidirectional. By arranging the head 510 of the operator 500 at the center of the hollow spheres constituting the panoramic images PI and PI (in this example, substantially omnidirectional), it becomes easy to understand.

The image processing device 320 receives the head of the operator 500 from the predetermined reference points α (for example, the yawing reference angle φy, the rolling reference angle φr, and the pitching reference angle φp in front of the working machine 200) in the panoramic images PI and PI. Relative reference point Δα (for example, relative yawing reference angle with respect to the reference point in front of the working machine 200) moved by 510 movements (specifically, yawing angle θy with respect to the reference posture of the head 510, rolling angle θr, and pitching angle θp). φy + θy, relative rolling reference angle φr + θr, relative pitching reference angle φp + θp) is calculated.

Further, the image processing device 320 is configured to cut out a part of the adjusted panoramic image PI, PI in the panoramic image PI, PI. Specifically, the image processing device 320 partially performs PIP, PIP at a cutting angle (β, γ) corresponding to the viewing angle of the operator 500 with reference to the relative reference point Δα calculated from the panoramic images PI, PI. It is designed to be cut out.

In this example, the line-of-sight detection unit 411 is a posture detection unit that detects the posture of the head 510 of the operator 500, but is a line-of-sight detection unit that detects the line of sight (eye movement) of the operator 500. There may be. In this case, if the response speed from the line-of-sight detection unit is too fast, the image processing device 320 can delay the response speed to perform the adjustment process or the cutout process.

FIG. 7 is a flowchart showing an example of the control operation of the display system 100 according to the first embodiment.

In the control operation of the display system 100 according to the first embodiment, as shown in FIG. 7, first, the image processing device 320 on the working machine side 110 has a plurality of captured image IMs captured by the plurality of camera units 310 to 310. Panorama images PI and PI are generated by ~ IM and IM ~ IM (step S101).

Next, the image processing device 320 performs a cutting process for cutting out a part of the generated panoramic image PI, PI, PIP, PIP (step S102).

Next, the image processing device 320 transmits the cut panoramic image PI, a part of the PI, PIP, PIP to the remote control device 420 on the remote control side 120 by wireless communication (step S103).

Next, the remote control device 420 of the remote control side 120 transmits to the display device 410 while receiving the panoramic image PI, a part of the panoramic image PI, PIP, PIP sent from the image processing device 320 of the work machine side 110 ( Step S104).

Next, the display device 410 displays while receiving the panoramic image PI, a part of the panoramic image PI, PIP, PIP sent from the remote control device 420 (step S105).

Next, the display device 410 transmits to the remote control device 420 while detecting the movement of the head 510 of the operator 500 (step S106).

Next, the remote control device 420 receives the movement of the head 510 of the operator 500 sent from the display device 410 and transmits it to the image processing device 320 of the work machine side 110 by wireless communication (step S107).

Next, the image processing device 320 of the work machine side 110 receives the movement of the head 510 of the operator 500 sent from the remote control device 420 of the remote control side 120, and panorama according to the movement of the head 510. Partial PIPs and PIPs of the image PIs and PIs are adjusted (step S108).

Then, the display system 100 according to the first embodiment repeats the processes of steps S101 to S108 described above until the processing operation is completed (step S109).

According to the display system 100 according to the first embodiment described above, the image processing device 320 transmits to the display device 410 in response to the movement of the head 510 of the operator 500 sent from the remote control device 420. Since the partial PIP of the panoramic image PI for the left eye and the partial PIP of the panoramic image PI for the right eye are adjusted respectively, the three-dimensional display is displayed on the display device 410 according to the movement of the head 510 of the operator 500. The field of view can be adjusted, and therefore the display image displayed on the display device 410 can be made to follow the movement of the line of sight of the operator 500. This makes it possible to improve the operability of remote control. Moreover, since the image processing device 320 transmits some PIPs and PIPs of the panoramic images PI and PI to the remote control device 420 by wireless communication, all the panoramic image PIs and PIs are transmitted to the remote control device 420 by wireless communication. Compared with the case, the traffic load on wireless communication can be reduced.

By the way, in a display system configured to move the camera itself to display the display image on the display device, it takes time to move the camera when moving the display image to be displayed on the display device.

In this regard, in the display system 100 according to the first embodiment, since the image processing device 320 has the panoramic images PI and PI (omnidirectional image or substantially omnidirectional image), the camera itself is moved. It is possible to eliminate the delay in the time required to move the camera as compared with the display system configured to display the display image on the display device.

Further, in the first embodiment, the plurality of camera units 310 to 310 are arranged at positions corresponding to positions in the horizontal direction (specifically, both the front-rear direction and the left-right direction) of the seats to be provided on the work machine 200. Therefore, the line-of-sight height when it is assumed that the center position of the lens in the camera units 310 to 310 is seated by a worker having an average physique (for example, height or sitting height) of the destination of the work machine 200. Since it is provided at the seating height position corresponding to, the display device 410 can display a part of the panoramic image PI, PI, PIP, PIP, which is the same as the view when the operator actually sits on the seat. it can.

(Second Embodiment)
FIG. 8 is a schematic configuration diagram schematically showing a display system 100 for remote control of the work machine 200 according to the second embodiment.

As shown in FIG. 8, the display system 100 according to the second embodiment displays the remote control devices 420 on the remote control side 120 as a plurality of remote control devices 420 to 420 in the display system 100 according to the first embodiment. The device 410 is a plurality of display devices 410 to 410 corresponding to the plurality of remote control devices 420 to 420, respectively.

In the display system 100 according to the second embodiment, substantially the same components as the display system 100 according to the first embodiment are designated by the same reference numerals, and are mainly different from the display system 100 according to the first embodiment. Explain to.

The image processing device 320 of the working machine side 110 cuts out a part of the panoramic image PI, PI, PIP to PIP, PIP to PIP, and partially cuts out the panoramic image PI, PI, PIP to PIP, PIP to PIP by wireless communication. It is configured to transmit to a plurality of remote control devices 420 to 420 on the remote control side 120. Here, the communication between the image processing device 320 on the work equipment side 110 and the plurality of remote control devices 420 to 420 on the remote control side 120 is a multiplexing communication in which a plurality of signals are simultaneously transmitted on one transmission line. Can be. The multiplexing communication is not limited to that, and examples thereof include multiplexing communication such as frequency division multiplexing (FDM) communication and time division multiplexing (TDM: Time Division Multiplexing) communication.

The plurality of remote control devices 420 to 420 on the remote control side 120 receive a part of the panoramic image PI, PI sent from the image processing device 320, PIP to PIP, and PIP to PIP, respectively, and receive the panoramic image PI, A part of the PIs, PIP to PIP and PIP to PIP, are configured to be transmitted to a plurality of corresponding display devices 410 to 410, respectively.

The plurality of display devices 410 to 410 on the remote control side 120 receive and receive a part of the panoramic images PI and PI sent from the corresponding plurality of remote control devices 420 to 420, PIP to PIP and PIP to PIP. The panoramic images PI and a part of the PIs PIP to PIP and PIP to PIP are displayed respectively. The plurality of line-of-sight detection units 411 to 411 (in this example, the plurality of display devices 410 to 410) each detect the movements of the heads 510 to 510 of the corresponding plurality of operators 500 to 500, and the plurality of detected operations. The movements of the heads 510 to 510 of the persons 500 to 500 are transmitted to a plurality of remote control devices 420 to 420 corresponding to each. The plurality of remote control devices 420 to 420 are heads 510 of a plurality of operators 500 to 500 sent from a plurality of line-of-sight detection units 411 to 411 (in this example, a plurality of display devices 410 to 410) corresponding to each of the plurality of remote control devices 420 to 420. The movement of 510 is transmitted to the image processing device 320 by wireless communication.

The image processing device 320 of the work machine side 110 is a part of the panoramic images PI and PI according to the movements of the heads 510 to 510 of the plurality of operators 500 to 500 sent from the plurality of remote control devices 420 to 420. PIP to PIP and PIP to PIP are adjusted respectively.

Further, the image processing device 320 cuts out a part of the adjusted panoramic image PI, PI, PIP to PIP, and PIP to PIP in the panoramic image PI, PI, respectively.

The processing flow of the display system 100 according to the second embodiment is shown in FIG. 7, except that the remote control device 420 is a plurality of remote control devices 420 to 420 and the display device 410 is a plurality of display devices 410 to 410. It is substantially the same as the processing flow of the display system 100 according to the first embodiment, and description thereof will be omitted here.

According to the display system 100 according to the second embodiment, the plurality of operators 500 to 500 visually recognize the display images displayed on the plurality of display devices 410 to 410 corresponding to each other at the same time in a desired field of view. This makes it possible to improve the safety of work as compared with the case where one operator 500 visually recognizes the display image displayed on the display device 410 as in the first embodiment.

(Third Embodiment)
The display system 100 according to the third embodiment is the panoramic image PI, a part of the PIP, PIP of the PI, cut out and processed by the image processing device 320 of the working machine side 110 in the display system 100 according to the first embodiment. The adjustment process is configured to be performed by the remote control device 420 on the remote control side 120.

In the display system 100 according to the third embodiment, substantially the same components as the display system 100 according to the first embodiment are designated by the same reference numerals, and are mainly different from the display system 100 according to the first embodiment. Explain to.

FIG. 9 is a block diagram showing a system configuration of an image processing device 320 on the work machine side 110 in the display system 100 for remote control of the work machine 200 according to the third embodiment. Further, FIG. 10 is a block diagram showing a system configuration of the remote control device 420 of the remote control side 120 in the display system 100 according to the third embodiment.

As shown in FIG. 9, the image processing device 320 on the work equipment side 110 generated a panoramic image PI for the left eye (data of all panoramic image PIs) and a panoramic image PI for the right eye (data of all panoramic image PIs). ) Is transmitted to the remote control device 420 of the remote operation side 120 by wireless communication.

As shown in FIG. 10, the remote control device 420 on the remote control side 120 has a panoramic image PI for the left eye (data of all panoramic image PIs) and a panoramic image PI for the right eye (data of all panoramic image PIs) sent from the image processing device 320. Received data of all panoramic image PIs), cut out a part of the received panoramic image PI for the left eye and a part of the panoramic image PI for the right eye, and cut out a part of the panoramic image PI for the left eye. And a part of the panoramic image PI for the right eye PIP is transmitted to the display device 410, respectively.

Specifically, the remote control device 420 temporarily stores the received panoramic image PI for the left eye and the panoramic image PI for the right eye in the storage unit 422.

The remote control device 420 is configured to perform a cutting process for cutting out a part PIP of the panoramic image PI for the left eye and a part PIP of the panorama image PI for the right eye stored in the storage unit 422.

The cutting process for cutting out a part of the panoramic image PI and PI by the remote control device 420 is the same as the cutting process for cutting out a part of the panoramic image PI and PI by the image processing device 320 shown in FIG. This is the process of, and the description thereof is omitted here.

The remote control device 420 transmits a part PIP of the panoramic image PI for the left eye and a panoramic image PI for the right eye to be transmitted to the display device 410 in response to the movement of the head 510 of the operator 500 sent from the display device 410. Adjust some PIPs of.

The adjustment process of adjusting the panoramic image PI, a part of the panoramic image PI, PIP, PIP according to the movement of the head 510 of the operator 500 by the remote control device 420 is performed by the image processing device 320 shown in FIG. This is the same process as the adjustment process for adjusting the panoramic image PI, a part of the PIP, and the PIP according to the movement of the head 510, and the description thereof will be omitted here.

Further, the remote control device 420 cuts out some PIPs and PIPs of the adjusted panoramic images PI and PI in the panoramic images PI and PI, respectively.

FIG. 11 is a flowchart showing an example of the control operation of the display system 100 according to the third embodiment.

In the control operation of the display system 100 according to the third embodiment, as shown in FIG. 11, first, the image processing device 320 on the working machine side 110 has a plurality of captured image IMs captured by the plurality of camera units 310 to 310. Panorama images PI and PI are generated by ~ IM and IM ~ IM (step S201).

Next, the image processing device 320 transmits the generated panoramic images PI and PI to the remote control device 420 on the remote control side 120 by wireless communication (step S202).

Next, the remote control device 420 of the remote control side 120 cuts out a part of the panorama image PI, PI while receiving the panorama image PI, PI sent from the image processing device 320 of the work machine side 110. The cutting process is performed (step S203).

Next, the remote control device 420 transmits the cut panoramic image PI, a part of the PIP, PIP of the PI to the display device 410 (step S204).

Next, the display device 410 displays while receiving the panoramic image PI, a part of the panoramic image PI, PIP, PIP sent from the remote control device 420 (step S205).

Next, the display device 410 transmits to the remote control device 420 while detecting the movement of the head 510 of the operator 500 (step S206).

Next, the remote control device 420 receives the movement of the head 510 of the operator 500 sent from the display device 410, and receives some PIPs and PIPs of the panoramic images PI and PI according to the movement of the head 510. Adjust (step S207).

Then, the display system 100 according to the third embodiment repeats the processes of steps S201 to S207 described above until the processing operation is completed (step S208).

According to the display system 100 according to the third embodiment, the remote control device 420 transmits a panorama for the left eye to the display device 410 in response to the movement of the head 510 of the operator 500 sent from the display device 410. Since the partial PIP of the image PI and the partial PIP of the panoramic image PI for the right eye are adjusted respectively, the three-dimensional field of view displayed on the display device 410 is adjusted according to the movement of the head 510 of the operator 500. Therefore, the display image displayed on the display device 410 can be made to follow the movement of the line of sight of the operator 500. This makes it possible to improve the operability of remote control. Moreover, since the remote control device 420 of the remote control side 120 performs the adjustment process of adjusting the panoramic image PI, a part of the PIP of the PI, the PIP, PIP according to the movement of the head 510 of the operator 500, the adjustment process is performed by the working machine. Compared with the case where the image processing device 320 on the side 110 is used, the time for transmitting the movement of the head 510 from the remote control device 420 on the remote control side 120 to the image processing device 320 on the work machine side 110 can be shortened. it can.

By the way, in a display system configured to move the camera itself to display the display image on the display device, it takes time to move the camera when moving the display image to be displayed on the display device.

In this regard, in the display system 100 according to the third embodiment, since the remote control device 420 has the panoramic images PI and PI (omnidirectional image or substantially omnidirectional image), the camera itself is moved. It is possible to eliminate the delay in the time required to move the camera as compared with the display system configured to display the display image on the display device.

(Fourth Embodiment)
FIG. 12 is a schematic configuration diagram schematically showing a display system 100 for remote control of the work machine 200 according to the fourth embodiment.

As shown in FIG. 12, the display system 100 according to the fourth embodiment displays the remote control devices 420 on the remote control side 120 as a plurality of remote control devices 420 to 420 in the display system 100 according to the third embodiment. The device 410 is a plurality of display devices 410 to 410 corresponding to the plurality of remote control devices 420 to 420, respectively.

In the display system 100 according to the fourth embodiment, substantially the same components as the display system 100 according to the third embodiment are designated by the same reference numerals, and are mainly different from the display system 100 according to the third embodiment. Explain to.

The image processing device 320 of the work machine side 110 is configured to transmit panoramic image PIs and PIs (data of all panoramic image PIs and PIs) to a plurality of remote control devices 420 to 420 of the remote control side 120 by wireless communication. Has been done. Here, the communication between the image processing device 320 on the work equipment side 110 and the plurality of remote control devices 420 to 420 on the remote control side 120 is the same as in the second embodiment, and description thereof will be omitted here. ..

The plurality of remote control devices 420 to 420 on the remote control side 120 receive the panoramic images PI and PI sent from the image processing device 320, respectively, and a part of the received panoramic images PI and PI PIP to PIP, PIP to The PIP is cut out, and a part of the cut out panoramic image PI, PI, PIP to PIP, and PIP to PIP are configured to be transmitted to a plurality of corresponding display devices 410 to 410, respectively.

The plurality of display devices 410 to 410 on the remote control side 120 receive and receive a part of the panoramic images PI and PI sent from the corresponding plurality of remote control devices 420 to 420, PIP to PIP and PIP to PIP. The panoramic images PI and a part of the PIs PIP to PIP and PIP to PIP are displayed respectively. The plurality of line-of-sight detection units 411 to 411 (in this example, the plurality of display devices 410 to 410) each detect the movements of the heads 510 to 510 of the corresponding plurality of operators 500 to 500, and the plurality of detected operations. The movements of the heads 510 to 510 of the persons 500 to 500 are transmitted to a plurality of remote control devices 420 to 420 corresponding to each.

The plurality of remote control devices 420 to 420 on the remote control side 120 are the heads of the plurality of operators 500 to 500 sent from the plurality of line-of-sight detectors 411 to 411 (in this example, the plurality of display devices 410 to 410). Partial PIP to PIP and PIP to PIP of the panoramic image PI and PI are adjusted according to the movements of 510 to 510, respectively.

Further, the remote control device 420 cuts out a part of the adjusted panoramic image PI, PI, PIP to PIP, and PIP to PIP in the panoramic image PI, PI, respectively.

The processing flow of the display system 100 according to the fourth embodiment is shown in FIG. 11 except that the remote control device 420 is a plurality of remote control devices 420 to 420 and the display device 410 is a plurality of display devices 410 to 410. The processing flow of the display system 100 according to the third embodiment is substantially the same, and description thereof will be omitted here.

According to the display system 100 according to the fourth embodiment, the plurality of operators 500 to 500 visually recognize the display images displayed on the plurality of display devices 410 to 410 corresponding to each other at the same time in a desired field of view. This makes it possible to improve the safety of work as compared with the case where one operator 500 visually recognizes the display image displayed on the display device 410 as in the third embodiment.

(Fifth Embodiment)
FIG. 13 is a schematic side view schematically showing a display system 100 for remote control of the work machine 200 according to the fifth embodiment.

As shown in FIG. 13, the display system 100 according to the fifth embodiment replaces the support member 330 provided in the work machine 200 in the display systems 100 to 100 according to the first to fourth embodiments. A support member 340 that can be raised and lowered and that can rotate in the vertical direction is provided.

In the display system 100 according to the fifth embodiment, substantially the same components as the display systems 100 to 100 according to the first to fourth embodiments are designated by the same reference numerals, and the description thereof will be omitted.

The support member 340 supports the support 331 that supports the plurality of camera units 310 to 310 and the support 331 at the upper end portion so that the plurality of camera units 310 to 310 maintain the horizontal posture, while the upper end portion is the upper portion. It has a support base (support arm 342 in this example) supported by the body 221.

In this example, the support arm 342 rotatably supports the support 331 around the axis (first fulcrum 342a) along the left-right direction at the upper end, while the support arm 342 along the upper body 221 at the lower end in the left-right direction. It is configured to be rotatably supported around the axis (second fulcrum 342b). Specifically, the support arm 342 is configured such that the second fulcrum 342b is located behind the first fulcrum 342a regardless of the rotation around the axis (second fulcrum 342b) along the left-right direction. The support arms 342 are a plurality of support arms 342 to 342 (two in the front-rear direction in this example). The plurality of support arms 342 to 342 have a parallel link configuration that supports the support 331 so as to be vertically movable in a state where the support arms 342 to 342 are arranged in parallel along the front-rear direction. The distance between the first fulcrum 342a to 342a and the second fulcrum 342b to 342b of the plurality of support arms 342 to 342 is a distance at which the plurality of camera units 310 to 310 maintain a horizontal posture. In this example, the first fulcrum 342a to 342a and the second fulcrum 342b to 342b of the plurality of support arms 342 to 342 are provided along the horizontal direction, and the first fulcrum 342a of the plurality of support arms 342 to 342 is provided. The distances between the ~ 342a and the second fulcrum 342b to 342b are all the same. As a result, the support member 340 maintains the plurality of camera units 310 to 310 in the horizontal posture regardless of the rotation around the axes (second fulcrum 342b to 342b) along the left-right direction of the plurality of support arms 342 to 342. can do. Here, the horizontal posture is the posture when the working machine 200 is installed on a horizontal surface as described above.

Further, the support member 340 includes a drive unit 343 that drives the support arms 342 to 342. The drive unit 343 operates by transmitting an operation command from the remote control device 230 on the remote control side 120, rotates the support arms 342 to 342, and moves the plurality of camera units 310 to 310 up and down. .. As a result, the operator 500 can move the plurality of camera units 310 to 310 up and down by remotely controlling the rotation operation of the support arms 342 to 342.

In this example, the support member 340 is seated by an operator whose movement range R in the ascending / descending direction of the center position of the lens in the camera unit 310-310 has an average physique (for example, height or sitting height) of the destination of the work machine 200. It is configured to include a seating height position H corresponding to the line-of-sight height when seated in. Here, the image processing device 320 transmits the current height position of the center position of the lens in the camera units 310 to 310 in the ascending / descending direction to the remote control device 420, and the remote control device 420 displays the current height position. It is transmitted to the device 410, and the display device 410 displays various index positions such as the maximum height position MAX of the center position of the lens, the minimum height position MIN, and the seating height position H in the camera units 310 to 310. Then, the current height position may be displayed. As a result, the operator 500 can recognize the current height position of the center position of the lens in the camera units 310 to 310.

Further, in the support member 340, when the center position of the lens in the camera units 310 to 310 is located at the seating height position H, the camera units 310 to 310 should be provided in the work machine 200 in the horizontal direction of the seat (specifically). It is configured to be located at an arrangement position corresponding to the position in the front-back direction).

The support arm 342 may be configured to support the support body 331 so as to be able to move up and down with the support body 331 fixed at the upper end portion.

According to the display system 100 according to the fifth embodiment, the plurality of camera units 310 to 310 are provided on the support member 340 that can be raised and lowered and that can be rotated in the vertical direction, so that the operator 500 is required. Accordingly, the height of the center position of the lens in the plurality of camera units 310 to 310, and by extension, the field of view height of the operator 500 can be adjusted. As a result, for example, the operator 500 can grasp a wider field of view of the surrounding situation of the work machine 200 from a bird's-eye view. Further, by operating the support member 340 so that the height positions of the plurality of camera units 310 to 310 are lowered, the work machine 200 can perform the work even if the work site is in a hole or a place where the ceiling is low. It will be possible to easily enter the site. Further, when the operator 500 directly looks at the surrounding situation (directly confirms) and operates the operation, a plurality of camera units 310 to 310 are operated by operating the support member 340 so as to fit in the work machine 200. The camera units 310 to 310 can be stored in the working machine 200. Further, the support arms 342 to 342 are configured such that the second fulcrums 342b to 342b are located behind the first fulcrums 342a to 342a, so that the camera units 310 to 310 are the first fulcrums in the working unit 220. It is possible to reliably photograph the working state in front of 342a to 342a.

(Sixth Embodiment)
The display system 100 according to the sixth embodiment is provided in the peripheral portion (near or close position) of the plurality of camera units 310 to 310 in the display systems 100 to 100 according to the first to fifth embodiments. It is equipped with lighting devices 350 to 350 and 350 to 350.

FIG. 14 shows the pair of cameras 311, 312 and the lighting devices 350 provided on the pair of cameras 311, 312 that constitute the camera unit 310 in the display system 100 for remote control of the work machine 200 according to the sixth embodiment. It is a schematic block diagram which saw an example of 350 from the front. The lighting devices 350 to 350 and 350 to 350 provided in the plurality of camera units 310 to 310 have the same configuration, and in FIG. 14, one of the camera units 310 to 310 is the camera unit 310. It is shown as a representative of the lighting devices 350 and 350 provided in.

As shown in FIG. 14, in the lighting devices 350, 350, the light emitting side faces the subject side at least a part of the peripheral edge portion of the lenses 311a, 312a of the pair of cameras 311, 312 (over the entire circumference in this example). It is provided. In this example, the illumination devices 350, 350 are a plurality of (eight in this example) light emitting elements 351 to 351 provided over the entire circumference of the peripheral edges of the lenses 311a and 312a of the pair of cameras 311, 312, respectively. It is equipped with 351 to 351 (specifically, a light emitting diode). The plurality of light emitting elements 351 to 351 and 351 to 351 are provided evenly or substantially evenly along the circumferential direction of the lenses 311a and 312a.

According to the display system 100 according to the sixth embodiment, the lighting devices 350 to 350, 350 to 350 are provided in the peripheral portions of the plurality of camera units 310 to 310, so that the lighting devices 350 to 350, 350 to 350 are provided. It is possible to effectively prevent shadows from being cast on the captured images captured by the plurality of camera units 310 to 310 due to the light emitted from the camera units.

(7th Embodiment)
By the way, at the work site, the work plan (for example, the work plan such as the depth and range of excavation), the rotation range of the work unit 220 (specifically, the rotation range of the upper body 221 and the boom 222, the arm 223 and It is extremely necessary for the operator 500 to recognize in advance the position of the bucket 224 or the position of the buried pipe such as the gas pipe or the water pipe and perform the work in order to improve the workability such as work efficiency and safety. is important.

From this point of view, the display system 100 according to the seventh embodiment is the work assistance information corresponding to a part of the panoramic image PI, PI, PIP, PIP in the display systems 100 to 100 according to the first to sixth embodiments. Partial Q1 and Q1 of Q and Q (for example, work plan, rotation range of work unit 220 or position of buried pipe such as gas pipe and water pipe, and other supplementary information) are shown in panoramic images PI and PI. Along with some PIPs and PIPs, the panoramic image PI and some PIPs and PIPs of the PIs are additionally displayed on the display device 410 to realize augmented reality (AR). Here, augmented reality is a technique for adding visual information related to the real environment to information in the real environment. Specifically, the image of the real environment taken by the camera unit 310-310 is combined with the image related to the real environment by a computer in real time. This is a technique for synthesizing images according to the movement of images of the camera units 310 to 310.

FIG. 15 shows, in the display system 100 for remote control of the work machine 200 according to the seventh embodiment, the panoramic images PI, a part of the PI, a part of the work assistance information Q, Q corresponding to the PIP, Q1, Q1. A display diagram showing an example of display screens D and D additionally displayed on the display device 410 in correspondence with the panoramic image PI and a part of the PI PIP and PIP and a part of the panoramic image PI and PI and the PIP and PIP. Is. In FIG. 15, as work assistance information Q, Q, buried pipes such as gas pipes and water pipes based on a map of the piping network buried under the ground G, G (part of work assistance information Q, Q Q1, An example of Q1) is shown. Further, since the partial PIP of the panoramic image PI for the left eye and the partial PIP of the panoramic image PI for the right eye have substantially the same configuration, in FIG. 15, a partial PIP of the panoramic image PI for the left eye and a partial PIP of the right eye A part of the panoramic image PI for PIP is shown in one figure, and the processing of their augmented reality will be described together.

The remote control devices 420, 420 in the first and third embodiments or the image processing device 320 in the first embodiment is a database prepared in advance in the display system 100 (for example, a storage unit 422 or a storage unit 422 in the remote control device 420). After cutting processing based on a database (database stored in advance in the storage unit 322 of the image processing device 320) or a database provided in a location different from the display system 100 (for example, a database downloaded from a server on the Internet). Panorama image PI, part of PI PIP, work assistance information corresponding to PIP Part of Q, Q Q1, Q1 after cutting processing Panorama image PI, part of PI corresponding to PIP, PIP after cutting processing The panoramic image PI and a part of the PI are added to the PIP and PIP.

Alternatively, the image processing devices 320, 320 in the first and third embodiments or the remote control device 420 in the third embodiment is a database prepared in advance in the display system 100 (for example, a storage unit in the remote control device 420). Cutting process based on 422 or a database stored in advance in the storage unit 322 of the image processing device 320, or a database provided in a location other than the display system 100 (for example, a database downloaded from a server on the Internet). The work assistance information Q and Q corresponding to the previous panoramic image PI and PI are added to the panoramic image PI and PI before the cutting process in correspondence with the panoramic image PI and PI before the cutting process. Then, in the process of cutting out the panoramic images PI and some PIPs and PIPs of the PIs, the corresponding work assistance information Q and Q1 and some parts Q1 and Q1 are also cut out.

As this database, for example, a database existing in a CAD (Computer Aided Design) model can be mentioned. The panoramic images PI and PI include, for example, position information (latitude, longitude) using the Global Positioning System (GNNS) in the working machine 200. Further, the work assistance information Q, Q is, for example, information that constitutes a panoramic image including position information (latitude, longitude) corresponding to the position information (latitude, longitude) of the panorama images PI, PI.

Then, the display device 410 displays the panoramic image PI, a part of the PI, a part of the work assistance information Q, Q corresponding to the PIP, Q1 and Q1 together with the panoramic image PI, a part of the PI, and the panoramic image PI. It is configured to additionally display a part of PI corresponding to PIP and PIP.

As a result, the operator 500 can recognize the work assistance information Q, Q in advance. For example, in the operator 500, the rotation position of the work unit 220 (specifically, the rotation position of the upper body 221 and the swing position of the boom 222, the arm 223, and the bucket 224) reaches a predetermined reference value in the work plan. Whether or not (for example, whether or not the standard work depth or the predetermined standard work range is exceeded), whether or not the work range of the work site is reached (for example, whether or not it touches the ceiling of the work site), and whether or not the work site It is possible to recognize whether or not it has reached the buried object (for example, whether or not it comes into contact with the buried pipe Q1 such as a gas pipe or a water pipe).

The configuration for realizing such augmented reality can be realized by using a conventionally known method, and detailed description thereof will be omitted here.

According to the display system 100 according to the seventh embodiment, the display device 410 has a panoramic image PI, based on a database prepared in advance in the display system 100 or a database provided at a location different from the display system 100. Work assistance information Q, part of Q, Q1 and Q1 corresponding to part of PI and part of PIP are made to correspond to part of panorama image PI and part of PI PIP and PIP together with part of panorama image PI and part of PI. By additionally displaying, the operator 500 can perform work assistance information Q, Q (for example, work plan, rotation range of the work part, position of buried pipe such as gas pipe or water pipe, etc., and other supplementary information. Information) can be recognized in advance, which makes it possible to improve workability such as work efficiency and safety.

The present invention is not limited to the embodiments described above, and can be implemented in various other forms. Therefore, such embodiments are merely exemplary in all respects and should not be construed in a limited way. The scope of the present invention is shown by the claims and is not bound by the text of the specification. Furthermore, all modifications and modifications that fall within the equivalent scope of the claims are within the scope of the present invention.

The present invention relates to a display system for remote control of a work machine, and is particularly applicable to an application for making a display image displayed on a display device follow the movement of the operator's line of sight.

100 Display system 110 Work machine side 120 Remote operation side 200 Work machine 210 Traveling body 220 Work part 221 Upper body 222 Boom 223 Arm 224 Bucket 230 Remote control device 231 Operation part 300 Work machine side components 310 Camera part 311 For left eye Camera 311a Lens 312 Right eye camera 312a Lens 320 Image processing device 321 Control unit 322 Storage unit 323 Communication unit 330 Support member 331 Support 331a Fixing member 332 Strut 340 Support member 342 Support arm 342a First fulcrum 342b Second fulcrum 343 Drive Unit 350 Lighting device 351 Light emitting element 400 Remote operation side component 410 Display device 411 Line-of-sight detection unit 420 Remote control device 421 Control unit 422 Storage unit 423 Communication unit 500 Operator 510 Head CB1 Connection cable CB2 Connection cable D Display screen G Ground H Seating height position IM Captured image MAX Maximum height position MIN Minimum height position PI Panorama image PIP Part of panorama image Q Work assistance information Q1 Part of work assistance information R Movement range d Interval Δα Relative reference point α Reference Point β Horizontal cutting angle γ Vertical cutting angle θp Pitching angle θr Rolling angle θy Yawing angle φp Pitching reference angle φr Rolling reference angle φy Yawing reference angle

Claims (13)

With the camera part
The captured image taken by the camera unit is cut out at a predetermined cutting angle corresponding to the viewing angle of the operator, and the shooting is performed according to the movement of the operator's head or eyeball received from an external device. An image processing device that performs adjustment processing to adjust the cropping angle of an image, and
It is a work machine equipped with
The image processing device is characterized in that when the response speed of the movement of the head or eyeball of the operator is faster than a predetermined response speed, the response speed is delayed to perform the adjustment process or the cutout process. Working machine to do. The working machine according to claim 1.
The camera unit is a work machine characterized in that the lens of the camera unit is provided at a height position corresponding to the line-of-sight height when the worker of the work machine sits on a seat. The captured image received from the image processing device that crops the captured image captured by the camera unit provided in the work machine at a predetermined cropping angle corresponding to the viewing angle of the operator is displayed, and the operator's head or eyeball is displayed. It is a display device for remote operation of a work machine that detects the movement of the operator and transmits the detected movement of the head or eyeball of the operator to the image processing device.
The display device displays work assistance information corresponding to the captured image together with the captured image in correspondence with the captured image .
The work assistance information is a display device for remote control of the work machine, characterized in that it is within the operable range of the work machine. The display device according to claim 3.
A display device characterized by displaying buried objects buried under the ground. With the camera part
The captured image taken by the camera unit is cut out at a predetermined cutting angle corresponding to the viewing angle of the operator, and the shooting is performed according to the movement of the operator's head or eyeball received from an external device. An image processing device that performs adjustment processing to adjust the cropping angle of an image, and
It is a work machine equipped with
The camera unit is a work machine characterized in that the lens of the camera unit is provided at a height position corresponding to the line-of-sight height when the worker of the work machine sits on a seat. The working machine according to claim 5.
A working machine characterized in that the camera unit is provided on a support member that can be raised and lowered and that can rotate in a vertical direction. The working machine according to claim 5 or 6.
A working machine characterized in that a lighting device is provided in a peripheral portion of the camera portion. A display system for remote control of work equipment
The camera unit provided on the work machine and
An image processing device that performs a cutting process for cutting a captured image taken by the camera unit at a predetermined cutting angle corresponding to the viewing angle of the operator.
A display device that displays the captured image transmitted from the image processing device, detects the movement of the operator's head or eyeball, and transmits the captured image to the image processing device.
With
The image processing device performs adjustment processing for adjusting the cutting angle of the captured image transmitted to the display device according to the movement of the head or eyeball of the operator sent from the display device. When the response speed of the movement of the operator's head or eyeball is faster than a predetermined response speed, the response speed is delayed to perform the adjustment process or the cutting process. Display system for. A display system for remote control of work equipment
The camera unit provided on the work machine and
An image processing device that performs a cutting process for cutting a captured image taken by the camera unit at a predetermined cutting angle corresponding to the viewing angle of the operator.
A display device that displays the captured image transmitted from the image processing device, detects the movement of the operator's head or eyeball, and transmits the captured image to the image processing device.
With
The image processing device adjusts the cutting angle of the captured image transmitted to the display device according to the movement of the head or eyeball of the operator sent from the display device.
The display device displays work assistance information corresponding to the captured image together with the captured image in correspondence with the captured image.
The working auxiliary information display system for remote operation of the working machine, which is a working range of the previous SL working machine. A display system for remote control of work equipment
The camera unit provided on the work machine and
An image processing device that performs a cutting process for cutting a captured image taken by the camera unit at a predetermined cutting angle corresponding to the viewing angle of the operator.
A display device that displays the captured image transmitted from the image processing device, detects the movement of the operator's head or eyeball, and transmits the captured image to the image processing device.
With
The image processing device adjusts the cutting angle of the captured image transmitted to the display device according to the movement of the head or eyeball of the operator sent from the display device.
The camera unit is provided for remote control of the work machine, wherein the lens of the camera unit is provided at a height position corresponding to the line-of-sight height when the worker of the work machine is seated on the seat. Display system. The display system according to claim 10.
A display system characterized by displaying buried objects buried under the ground. The display system for remote control of the work machine according to any one of claims 8 to 11.
The camera unit is a display system for remote control of a working machine, which is provided on a support member that can be raised and lowered and that can rotate in a vertical direction. A display system for remote operation of the working machine according to any one of claims 8 to claim 1 2,
A display system for remote control of a work machine, characterized in that a lighting device is provided in a peripheral portion of the camera unit.

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