JPWO2016163035A1 - Mobile enclosure control interface - Google Patents

Abstract

Provided is an interface that can be easily operated without sacrificing the movement performance of a movable casing. Also, to realize a mobile housing that is easy, easy to use and safe for many people. In particular, in an operation mode using a sensing device, to provide a control interface that allows the pilot to coexist with the operation mode of the moving case and the mode of semi-autonomous operation. A moving housing includes a multi-dimensional input device and a plurality of movement modes. The multi-dimensional input device receives an operation state as operation coordinates in a multi-dimensional space, and each corresponds to a plurality of movement modes. An operation coordinate range is set, and the multi-dimensional input device is used for switching the movement mode. The movement mode is a different movement operation of the moving housing for any operation coordinate input, or the movement mode is the operation coordinate range. Provides a control interface that makes the movable housing a single moving motion for any operation coordinate input

Description

  The present invention relates to a control interface for a movable casing that can move forward and backward, curve, and turn on the spot by independently controlling forward and reverse rotation of a plurality of drive wheels. Examples of the moving housing include an omnidirectional moving vehicle using an electric wheelchair, a crawler robot, and an omni wheel.

  Conventionally, in an opposed two-wheel drive type moving housing such as an electric wheelchair, an interface that can be controlled by a rider using a joystick has been provided. For joystick operation, the forward / backward operation is generally assigned to the forward / backward movement of the moving case, and the left / right operation is assigned to the rotating action of the moving case. It has been.

  In Patent Document 1, regarding the danger of reverse operation, a control interface that prohibits traveling in the reverse direction and uses a reverse switching unit different from the joystick to temporarily change to a state in which only reverse operation is possible. providing.

  In Patent Document 2, for a joystick-type electric wheelchair, when a new handle-type operation unit is mounted on the control unit, a forward mode / reverse mode switching unit and an accelerator unit capable of giving an output instruction in absolute value are used. Thus, a control interface for simulating an operation method by a handle operation by a signal conversion circuit is provided.

In Patent Document 3, in order to realize operability close to the user's image, a control interface is provided that sets a turning pass target point from the tilt angle of the joystick and generates a speed of passing through the target point. In addition, in order to improve the safety of the vehicle body control, the structure is such that the centrifugal force and the wheel speed during traveling are limited so as not to exceed the specified values.
JP 2014-64620 A JP 2005-328879 A JP 2001-104396 A

  In the control interface disclosed in Patent Document 1, it is shown in the embodiment that the backward prohibition is canceled by the user's switch operation. For this reason, switching to the backward movement requires a new operation in place of the joystick, which is not a simple operation means for all users. Since the forward and backward movements are a single movement form used when the user performs direct maneuvering, a simpler procedure is possible if switching can be performed using only the joystick.

  Further, in the embodiment of Patent Document 1, it is indicated that “the state notification means reduces the confusion of the operator due to the change in the relationship between the operation of the joystick and the operation of the electric wheelchair (when reversing)”. , This does not substantially organize the operational relationship, suggesting that user confusion remains. Of the operations indicated as “fixed-position rotation mode” in the embodiment, only “111d and 111e restricted as in-situ turning” is the maximum speed at the time of reverse as a control parameter setting in the controller device of the electric wheelchair for a long time. As the behavior of adjusting the value to zero, almost the same movement can be simulated, and it can be said that it is a category of the existing operation.

  In the control interface disclosed in Patent Document 2, a handle type control device and a forward / backward changeover switch attached thereto are shown in the embodiment. For this reason, as in Patent Document 1, in order to switch the running state, a new operation in place of the joystick is required, and since the handle type control device and the signal conversion circuit are used together, the simple procedure is I can not say.

  In the control interface disclosed in Patent Document 3, operability like that of an automobile (steering wheel) is simulated by only a joystick operation without an additional structural part. Therefore, it can be said that the traveling performance of the original movable casing is impaired. In addition, the limitation on centrifugal force and wheel speed for improving safety during driving shows the method that is applied to the final determined output, so the same restriction is applied to all users. Will be implemented. However, one limitation is not a safe and comfortable ride for all users.

  In any of the above-mentioned patent documents, the control of the movable casing is premised only on the operation form that is directly operated by the user. However, in order to improve safety and efficiency, a sensor that detects the surrounding situation is used. It is also a problem to realize a system, a tracking operation form based on sensor data, a semi-autonomous operation form, an appropriate operation interface when using this, and a control interface in which these can be incorporated.

Means to solve the problem

In order to solve the above problems, in the present invention,

  Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,

  The moving case has a multi-dimensional input device and a plurality of movement modes, and the multi-dimensional input device has an operation state input as operation coordinates in a multi-dimensional space, and the plurality of movement modes are set as a predetermined operation coordinate range. The multi-dimensional input device is used for switching the movement mode, and the movement mode is a different movement operation for the arbitrary operation coordinate input, or the movement mode is any operation coordinate within the operation coordinate range. Provided is a control interface for a mobile casing characterized in that the mobile casing is also moved into a single moving operation in input.

  As represented by an electric motor, the prime mover can control forward rotation and reverse rotation, and the moving housing can be moved by rotating a tire, a crawler, or the like. The moving housing has at least two prime movers and can be controlled to move forward and backward, curve, and turn on the spot.

  The multidimensional input device may be a joystick-type steering device listed in the prior art document. Further, the touch pad type information terminal may be touched and operated. These can be interpreted as a two-dimensional steering device, and it can be considered that the steering is input as two-dimensional coordinates. An input device such as a sensing device that directly detects a spatial position of a finger or a part of the user's body or a three-dimensional mouse including a rotation operation may be used as the three-dimensional steering device.

  As in the prior art document, the moving housing moves forward when the steering device indicates a forward input, and the moving housing moves backward when the backward input is made, and the moving housing moves according to the input in the left-right direction. Generally, the whole rotates left or right, and the motion is generated by combining the front, rear, left and right inputs.

  Here, in the present invention, the operation form and the movement mode corresponding to the usage scene of the movable casing are defined in the movable casing. A corresponding operation coordinate range is set for each of the plurality of movement modes, and a multidimensional input device is used to switch the movement modes. FIG. 19 shows an example of operation modes and movement modes in the present invention. For example, in a direct operation mode for direct operation of the moving housing, there are a forward mode, a reverse mode, and a neutral mode as the movement mode. In these movement modes, the movement case is moved differently with respect to an arbitrary operation coordinate input in accordance with the movement mode applied to the movement case. Specifically, for example, when the forward mode is applied, the backward movement is suppressed even when the backward input is performed, but when the backward mode is applied, the backward movement is performed according to the backward input. In addition, when the mobile housing implements the follow-up operation mode or the semi-autonomous operation mode based on the data of the sensing device, a start mode, an end mode, a temporary stop mode, a traveling direction, a course selection mode, and the like are assigned as movement modes. These movement modes make the movable casing a single movement operation for any operation coordinate input within the operation coordinate range. Unlike the configuration in which the target output is determined on a one-to-one basis from the operation coordinate input, which is also assumed in the prior art documents, a unique mechanism is introduced together with the switching procedure. Note that the safe maneuvering mode means that the device is in the direct operation mode and automatically assists such as deceleration and stop based on the data of the sensing device.

  The neutral mode is a mode for switching the movement mode of the movable casing. For example, when the user wants to shift from the forward mode to the reverse mode, the mode can be switched once through the neutral mode. The mode is switched based on the user's intention as in the neutral in the automobile mission.

  In addition, as presupposed in the prior art documents, a selection type speed mode consisting of a plurality of stages is provided, and the maximum speed for the operation is switched from the multi-dimensional input device by selecting this according to the user's preference; To do. At this time, by adding a new restriction in the operation coordinates of the multidimensional input device, a stepwise restriction for each user according to the speed mode is applied. Furthermore, only when selecting a speed mode larger or smaller than an arbitrary speed mode, not only the existing selection input means but also the operation coordinates of the joystick are operated within a predetermined coordinate range, or other than the selection input means. By operating a button or a touch panel, a speed mode larger or smaller than an arbitrary speed mode can be selected.

  In a mobile housing equipped with a sensing device attached to the mobile housing and a control device capable of processing sensor data from the sensing device and outputting a control signal to the prime mover, an operation mode using the sensing device according to the intention of the user The configuration can be switched to. The operation mode using the sensing device is based on the information of the sensing device, for example, configured to move while avoiding obstacles, or to travel along roads, corridors, along point markers, and line markers. The configuration is instructed by a multidimensional input device. You may comprise so that a specific person and another moving housing | casing may be recognized with a sensing device, and a position may be identified and followed. As an operation mode using the sensing device, it may be configured such that the position of the moving housing can be automatically moved toward the destination by comparing it with a map held inside. Also, when it is determined by the sensing device that the mobile case is likely to come into contact with a pedestrian or another mobile case, it is decelerated, stopped, or avoided without following the direct maneuvering instructions by the user's joystick operation It may be configured to take action. In particular, in the present invention, the operation mode using the sensing device is configured to be able to instruct start, end, pause, travel direction, and route selection as the movement mode.

  In addition, by separating the multi-dimensional input device from the motor controller and introducing a relay interface, it is possible to improve autonomy and safety in cooperation with a host computer and an external sensor system.

  According to the present invention, various different operation commands can be easily input by switching and operating a plurality of movement modes with only the multidimensional input device in each operation mode. By reducing the number of operations, a simple and intuitive control interface can be provided. Further, by switching the movement mode, it is possible to provide an interface that can be easily operated without sacrificing the movement performance of the moving casing.

  Further, by applying a restriction to the input from the joystick, the output restriction is applied to each of the speed modes composed of a plurality of stages, so that it is possible to realize a mobile housing that is easy to use for many people and is safe. In the operation mode using the sensing device, it is possible to provide a control interface that is flexible and easy to operate by coexisting the operation by the user and the autonomous traveling function of the moving housing.

  Furthermore, the introduction of the relay interface makes it possible to construct an additional function such as positioning, follow-up traveling, automatic driving, etc., and the cooperation between joystick operation and automatic control by the user, leading to improvement in safety and convenience.

Hereinafter, the control interface of the mobile housing according to the embodiment of the present invention will be described with reference to FIGS.
First, the moving housing in the present embodiment will be described with reference to FIGS.
FIG. 1 is an external view of an electric wheelchair type that is a moving housing. FIG. 2 is a front view of the movable casing, and FIG. 3 is a left side view of the movable casing.

  1 to 3 is a moving case, and in this embodiment, a moving case of a wheelchair type. 1 in FIG. 1 is a seat for the passenger. The moving housing includes a driving wheel 21 for moving, a caster 22, and a prime mover 20 for rotating the driving wheel 21. The prime mover 20 is an electric motor in this embodiment, and electric motors are attached to the left and right in order to drive the two driving wheels facing left and right, respectively, and the driving wheels 21 are rotated forwardly and reversely via a reduction mechanism, respectively. It is possible to perform a short-circuit brake between terminals and a release-free operation between terminals. By driving the drive wheel 21, the movable casing 1 can perform operations such as forward movement, backward movement, curve, and on-site turning. The prime mover may drive the crawler instead of the driving wheel. By adopting a crawler, traversability is improved and it is possible to move on rough terrain. Further, a plurality of types capable of omnidirectional movement may be employed as the peristaltic wheel. When omnidirectional movement type driving wheels are employed, it is possible to move in the lateral direction. Further, a lock structure using an electromagnetic brake or a lever mechanism may be provided around the prime mover 20.

  1-3 is a joystick used as a multidimensional input device in this embodiment. The traveling direction and speed intended by the operator can be reflected on the movable casing by the tilt angle and the tilt direction of the joystick 3. In addition, although not shown in the drawing, it has an operation button and other input means, and has a function of a speed mode in which setting values such as maximum speed and acceleration can be selected in a plurality of stages. As a multi-dimensional input device, a touchpad type smart terminal may be touched and operated, or it may be operated with a foot, face, eye movement or mouth. These can be interpreted as a two-dimensional steering device, and it can be considered that the steering is input as two-dimensional coordinates. In addition, a sensing device that directly detects the spatial position of a finger or a part of the pilot's body or an input device such as a three-dimensional mouse may be used as a three-dimensional steering device. An example can be applied.

  Reference numeral 4 in FIGS. 1 to 3 denotes a scanner type laser distance sensor used as a sensing device. A laser distance sensor that can measure shape data on the scanning plane is used to determine the position of an obstacle, to specify the position of a specific tracking target, and to determine the self-position on the map by comparing the environment with the map. used. As a sensing device, a camera capable of acquiring a distance and an image, a stereo camera, a millimeter wave radar, an ultrasonic sensor, or the like can be used.

  FIG. 4 simply shows the overall system configuration in this embodiment. Information from the joystick 3 and the laser distance sensor 4 is input to the arithmetic unit 7, and a target command signal is sent from the arithmetic unit 7 to the driver device 8 that drives the electric motor. Examples of the target command signal sent to the driver device 8 include a target speed, a target acceleration, a target torque, a target voltage, and a target current. Based on the target command signal from the arithmetic unit 7, the driver device 8 adjusts the current flowing through each electric motor 20 by adjusting forward rotation, reverse rotation, output magnitude, brake, etc., for example. To drive. The rotation information of the electric motor 20 or the driving wheel 21 may be transmitted to the arithmetic device 7 by the pulse signal 81 or the like and used for control. In addition, the power supply voltage may be detected by the arithmetic device 7 or the driver device 8 so as to adjust the drive so that the output to the prime mover does not change due to fluctuations in the drive power supply voltage supplied to the driver device 8. In addition, the calculation device 7 or the driver device 8 detects the current flowing through the electric motor 20 and adjusts the drive so that the output to the prime mover does not change due to fluctuations in the external load on the moving housing including uphill and downhill. You may make it the structure to carry out. Although not shown, a power source for operating each element is provided. Each signal path may include battery information, speed mode information, motor rotation state information, and attached button input information. The separation of the functions of the arithmetic device 7 and the driver device 8 is not limited to this, and it is sufficient that the two devices have a single function.

  FIG. 5 shows details of the joystick 3 used as a multidimensional input device in this embodiment. The joystick 3 is mainly composed of a lever 31 and a display operation unit 33. The display operation unit 33 can display the state of the movable casing and the applied movement mode, and can perform operations such as setting. The operator maneuvers the traveling direction and speed of the movable casing by tilting the lever 31. A tilt angle L when the lever 31 is tilted is indicated by 311 and is limited within a predetermined movable range of the lever 31. In this embodiment, the tilt angle L is expressed as a ratio to the maximum tilt angle for convenience. That is, the tilt angle L at the movable range limit is set to 1, and the tilt angle L is expressed in a range of 0 to 1. Note that the multi-dimensional input range does not necessarily have to be a perfect circle with a fixed radius, and may be an ellipse or a polygon.

  FIG. 6 is a view of the joystick 3 as viewed from directly above, and the upward direction of FIG. 6 is the moving direction of the movable housing. FIG. 6 shows coordinate axes when the lever 31 of the joystick 3 is placed at the origin. FIG. 312 shows an example when the lever 31 is tilted diagonally to the left. In this embodiment, the traveling direction of the movable casing is expressed as the x direction, and the direction rotated 90 degrees counterclockwise from the traveling direction is expressed as the y direction. In the present embodiment, the tilting direction of the lever 31 is expressed by a counterclockwise angle when the x-axis is 0 degree. That is, when the lever 31 is tilted in the traveling direction, the tilt angle is 0 degrees, when the lever 31 is tilted to the left with respect to the traveling direction, it is 90 degrees, and when the lever 31 is tilted to the right, − Expressed as 90 degrees. When the lever 31 is tilted right behind, it is expressed as 180 degrees or -180. A coordinate expression method when the lever 31 is tilted in the direction 312 in FIG. 6 will be described with reference to FIG. When the lever is tilted in the direction 312, the tilting direction θ of this operation is 45 degrees. The tilt angle L is 0.8. In this way, the operation information can be expressed using the tilt direction θ and the tilt angle L. The operation information can be interpreted as being expressed in a polar coordinate system of θ and L, and when this is converted into xy coordinates, it can be converted using Equation 1 below.

  First, the neutral mode, the forward mode, and the reverse mode will be described using the operation coordinates shown in FIG. The neutral mode is applied immediately after the control interface is turned on. The neutral mode is a mode for selecting another mode. When the neutral mode is applied, the forward operation mode is applied when the operation coordinates of the lever operation are moved to the forward operation mode area 61. When the forward mode is applied, unless the lever operation is moved to the neutral mode area 60, only the forward movement or the in-situ turning movement is allowed. That is, when the forward mode is applied, the backward operation is not performed even if the lever is tilted backward. To perform the backward movement, return the lever once, apply the neutral mode by entering the operation mode into the neutral mode area, further tilt the lever back, and move the operation coordinate to the backward mode area 62 to move backward. Apply the mode and perform the backward movement. Similar to the forward mode, when the reverse mode is applied, the forward operation is not performed even if the operation lever is tilted forward. By switching the mode once through the neutral mode, an easy-to-operate control interface similar to driving a car can be realized. Switching to the neutral mode can be set to switch the mode when the operation coordinates stay within a predetermined coordinate range for a predetermined time. For example, it is applied to the neutral mode when the state where the tilt angle L is 0.05 or less is continued for 0.2 seconds. By switching the mode when the operation coordinates stay for a predetermined time, there is an effect of preventing malfunctioning contrary to the intention of the driver in the mode switching. Further, the fact that the mode has been switched may be indicated on the display / operation unit 33, or the operator may be notified that the mode has been switched by sounding an operation sound. The shape of the neutral mode area 60 is not limited to a circle, and may be a polygon. Similarly, the forward mode area 61 and the reverse mode area 62 are not limited to a sector, and are configured as a polygon. These three areas are not necessarily adjacent to each other, and may be arranged independently or overlappingly. In the case of duplication, the movement mode may be switched only at a place where there is no duplication. In this operation mode, the multi-dimensional input device is used for switching the movement mode, and the movement mode is characterized in that the moving casing is moved differently for any operation coordinate input.

  The forward mode will be described with reference to FIG. The forward mode includes a forward area 611 and spot rotation areas 612 and 613. In the range where the tilting direction θ shown in the forward area 611 in FIG. 9 is ± 90 degrees, the output from the operation coordinates to the prime mover can be determined based on, for example, the following formula 2 as in the conventional technique.

In Equation 2, v is the target translational movement speed of the movable casing, and ω is the target rotation speed. V _max is the maximum translation speed or limited translation speed of the moving casing determined in advance for each speed mode. Similarly, ωmax is the maximum rotational speed or maximum limiting speed of the mobile casing determined in advance for each speed mode. Is speed. Based on the target v and ω, the arithmetic unit determines a target rotational speed of each prime mover and outputs a control signal for the prime mover. The translational acceleration and the rotational acceleration may be determined by calculating at the same time, or a configuration in which a preset value is adopted may be used.

In the forward mode, the coordinate range of x <0, which is the backward range where the operation coordinates exceed ± 90 degrees, is set as the spot turn range, and the spot turn operation is performed. When the operation coordinates are in the spot turn area 612 on the left rear, the left turn is performed on the spot, and when the operation coordinates are in the spot turn area 613 on the right rear, the turn is performed on the spot. In this case, v and ω can be determined based on, for example, the following formulas 3 and 4. Equation 3 is the same as in Equation 2 when V _max = 0.

  In forward mode, by assigning the rear range to the turn operation on the spot, the moving housing will not stop against the intention of the operator, and when using a sensing device with a blind spot behind it, do not move backward Increases safety.

  The reverse mode will be described with reference to FIG. In the reverse mode, a reverse area 621, a suppression area 622, and a stop area 623 are provided. When the lever operating coordinates are in the retreat area 621, the output to the prime mover can be determined using, for example, the following Equation 5.

  Further, in order to realize a control feeling similar to that of an automobile, the output to the prime mover may be determined by reversing the left and right of the operation coordinates as shown in Equation 6 below. Thereby, since a movable housing | casing can be moved to the direction which fell the lever, maneuvering becomes easy.

  Furthermore, the operation mode that does not use conventional mode switching, the operation method that applies Formula 3 or Formula 4 to the entire operation range without using conventional mode switching, and the reverse mode that uses the mode switching described above, It may be configured so that it can be selected from two or more settings as to which of Equation 5 and Equation 6 is applied.

  In a conventional electric wheelchair, for example, if the joystick is set to “rear + left”, the vehicle will move backward to the right because the vehicle will move back to the right. The problem was that it was difficult to control. In the present embodiment, as shown in Equation 6, the interface to be easily operated by an operation method similar to that of an automobile is provided by using both the left and right of the operation coordinates to be reversed to determine the output to the prime mover and the mode switching. be able to. In addition, by adopting a configuration that can be selected from two or more settings, it is possible to select an interface that is easy to control for each operator, the conventional operability of an electric wheelchair, simple operability like a car, children It is possible to provide an interface that is easy to accept for many pilots, such as operability that does not reverse the direction at all.

  In the reverse mode, when the operation coordinates are in the stop area 623, the output to the prime mover is set to 0, and the moving housing is stopped. That is, even if the lever 31 is tilted forward in the backward mode, it does not move forward and stops on the spot. Further, when the operation coordinates are in the suppression area 622 between the retreat area 621 and the stop area 623, the operation of the moving housing is suppressed. For example, in the restraining area 622, as the tilting direction of the lever 31 approaches +90 degrees and −90 degrees from around +135 degrees and −135 degrees, the target translation speed v and the target rotational speed ω of the moving housing are less than 1 and a coefficient of 0 or more. To reduce the output value by the same ratio. As a result, as the x coordinate of the operation coordinate approaches 0, the movement of the movable casing is suppressed, and the backward movement is continuously suppressed, so that the behavior of the movable casing changes rapidly at the boundary of the reverse area 621. Can be avoided. Further, since the reverse mode does not include the movement of the spot turn, when Formula 6 is selected, it is possible to prevent the confusion of the driver whose rotation direction of the spot turn is reversed between the forward mode and the reverse mode. The area setting shown in FIGS. 9 and 10 is not limited to this, and can be expressed by an arbitrary shape.

  In the present embodiment, the y-axis of the operation coordinates and the target rotation speed may be defined by a relational expression that is not a linear function. For example, the relational expression shown in the following mathematical formula 7 can be used.

  In Equation 7, the sign function returns the sign of the input value, and the coefficient a is a real number of 1 or more. An example in which a is 1.5 is illustrated using FIG. In the graph of FIG. 11, the horizontal axis represents the absolute value of the y coordinate of the operation coordinate, and the vertical axis represents the ratio of the absolute value of the target rotational speed to the maximum rotational speed as a percentage. A graph 111 shows a case defined by a linear function as shown in Formula 2, and a graph 112 shows a case defined by a relational expression that is not a linear function shown in Formula 7. When defined by a linear function, the rate of change of the target rotational speed with respect to the y coordinate is constant, whereas when defined by Equation 7, the rate of change of the target rotational speed is within a range where the absolute value of the y coordinate is small. In the range where the absolute value of the y-coordinate is small and large, the rate of change of the target rotational speed is also large.

  This makes it possible to readjust the balance of movement by operations such as facilitating fine adjustment of the direction when going straight, while increasing the maximum rotational speed of the mobile case in turn when the pilot is maneuvering. Therefore, the effect of improving the handling feeling can be obtained. In Equation 7, the power of the coordinate value is used as the relational expression, but as a mathematical function that is not a linear function, a polynomial function, an exponential function, a trigonometric function, or the like may be used in addition to the power function. Further, the function of the y coordinate and the target rotation speed is expressed using a discrete table, the table data is stored in advance in the arithmetic unit, and the target rotation speed corresponding to the y coordinate is referred to from the table data. good. When the relational expression is defined using a discrete table, an effect of reducing the calculation load of the arithmetic device can be obtained. Furthermore, a different coefficient a may be used for each speed mode, or different mathematical functions and table definitions may be used. Moreover, you may make it the structure which applies these calculations to a translation target speed.

  Furthermore, different functions can be realized by applying these ideas to the rotational acceleration instead of the target rotational speed. The rotational acceleration is not a constant, and the rotational acceleration is small in the range where the absolute value of the operating coordinates is small, and the rotational acceleration is increased in the range where the absolute value of the operating coordinates is large. At this time, a linear function, a mathematical function, or a discrete table may be used. In deceleration, the rotational acceleration may be adjusted in the same way, or a constant may be used, or the calculation is performed so that it stops at a predetermined time according to the rotational speed immediately before the deceleration or the current target rotational speed. You may set a numerical value. In addition to this, in the coordinate axes on the multi-dimensional space for determining the target speed, the relationship between the coordinate value of the operation coordinate and the target speed is not a linear function, but the application of the minimum target speed in the specified time range or every specified time. A time delay function such as increasing the target speed may be used. By applying the minimum target speed in the specified time range, the effect of suppressing the backlash of the moving housing due to the rattling of the operation is produced, and by increasing the target speed every specified time, it is longer until the original target speed is reached. The acceleration can be changed in a pseudo manner by taking time. In addition, in the adjustment of the rotational acceleration and the application of the time delay function, translation (X axis) and rotation (Y axis) may be handled independently, or the tilt direction θ is performed only on the tilt angle L. It is also possible to adopt a configuration in which no adjustment or application is performed.

  The function of limiting the translation speed and the rotation speed in each speed mode in this embodiment will be described. In the present invention, the speed limit is expressed on the operation coordinates and is limited. FIG. 12 shows an example of the restriction region expressed on the operation coordinates and the restriction method. The graph shown in FIG. 12 is two-dimensional operation coordinates, and the vertical axis and the horizontal axis are the absolute values | x | and | y | of the operation coordinates, respectively. An example of the speed limit boundary is shown by a solid line 121 in the graph. The area above the speed limit boundary 121 is the speed limit area. The speed limit boundary 121 and the speed limit area can be expressed, for example, by the case where the limit threshold b = 0.5 in the following formula 8.

  The speed limit boundary 121 can be expressed using, for example, the following formulas 9 and 10 in addition to formula 8, and a single speed limit area may be configured by superimposing a plurality of these. The limit thresholds c and d are set as arbitrary real numbers.

  If the operation coordinates are in a region that is not the speed limit area, the operation coordinates are output without change. An example of a restriction method when the operation coordinates enter the speed restriction area will be described. For example, when the operation coordinates are at 122 in FIG. 12, the operation coordinates are in the speed limit area and the speed is limited. Here, the x coordinate and the y coordinate of the operation coordinates 122 are reduced at the same rate so as to be positioned on the speed limit boundary 121, and the coordinates of the point 123 on the speed limit boundary 121 are adopted as the final operation coordinates. . In other words, the coordinates of the intersection between the straight line connecting the operation coordinates 122 and the origin and the speed limit boundary 121 are adopted as the final operation coordinates. In addition, it may be the same that the reduction is performed at the same rate, but the configuration may be reduced to a smaller value as indicated by a point 124. For example, “the length from the origin to the point 123 ÷ the length from the origin to the operation coordinates 122” is converted into a ratio when the speed limit boundary is set to 100%. Based on these limited operation coordinates, the target translation speed and target rotation speed can be determined by applying each speed mode, and the limit at the time of output for each speed mode can be configured based on one speed limit. . For this reason, for example, when a person who is not confident in maneuvering selects the slow speed mode, the speed limit area is applied as a slower speed accordingly, and a person who is confident in maneuvering operates By selecting the fast speed mode, the restricted area is also applied as a fast speed, so it is not suitable for many users, rather than a single speed limit based on the movement limit of the moving housing as in the prior art. You can build a speed limit to provide.

  The speed mode can be selected with the operation buttons or other input means as described above, but only when selecting a larger or smaller speed mode with respect to the arbitrary speed mode, an operation used for normal selection. Select not only the buttons and input means but also the operation coordinates of the multi-dimensional input device within the specified coordinate range, or select the set value larger or smaller than the speed mode by operating the buttons and touch panel You may make it the structure which can be made. For example, when the speed mode consisting of a plurality of stages is set to, for example, five stages, the speed modes 1 to 3 are configured not to perform reverse traveling according to the above formulas 2 and 3 in order to realize simple operability, The speed modes 4 to 5 are specially configured to use a movement mode consisting of Equations 5 and 6. While the speeds 1 to 3 can be selected by the operation buttons and input means used for normal speed mode selection, when selecting the speed modes 4 to 5, different operations are required. Operators using configurations that are not simple operations can be easily assigned.

  In the present embodiment, by using the sensing device, it is possible to realize a plurality of configurations for an operation mode different from the direct operation of the moving housing by the multidimensional input device. In this embodiment, a laser distance sensor is used as a sensing device. As shown in the sensing device 4 of FIGS. 1 to 3, in this embodiment, two laser distance sensors are arranged up and down to sense the surroundings around the front of the traveling. FIG. 13 shows an image diagram of sensing data. The laser distance sensor 131 is a device that senses the position and shape of an object by measuring the distance to the object on the scanning surface. The sensing area on the scanning plane is, for example, a measurable area within a certain area 132 shown in FIG. For example, when there is a pedestrian or the like in the measurement area, the measurement data 133 and the measurement data 144 are measured. The measurement data is updated at a constant cycle, and by processing in the time direction, for example, the moving direction and moving speed of a pedestrian can be detected. In the present embodiment, sensing data is used as an operation mode different from the direct operation of the mobile housing by the multi-dimensional input device, and any one or all of a safe maneuvering mode, a compulsive mode, and a semi-autonomous mode. A configuration in which one can be selected.

  A safe operation mode will be described. The safe maneuvering mode is an operation mode for the purpose of avoiding a contact accident of a moving housing or reducing damage. The moving housing has a function of automatically applying a brake and decelerating when it is determined that there is a risk of contact based on the sensing data when the operator is maneuvering with the multi-dimensional input device. When it can be determined that there is an obstacle such as a pedestrian in the traveling direction, as shown in the sensing data 133 in FIG. 13, a configuration is adopted in which the vehicle is decelerated by reducing the output of the moving housing or applying a brake. Here, the strength of the brake is defined by Equation 11 below.

In Formula 11, F _brake is the strength of the brake. Depending on the degree of the strength of the brake, the output to the electric motor is simply reduced, or the electric motor generates torque in the reverse direction. The moving housing is decelerated by a simple brake mechanism. D is the distance to the obstacle, as shown in FIG. k ₁ is a constant, and the first term of Formula 11 is based on the idea that the brake strength is defined in inverse proportion to the distance to the obstacle. That is, when the distance to the obstacle is far, the brake is weak, and when the obstacle is near, the vehicle is decelerated with a strong braking force. V is the relative speed between the obstacle and the moving housing, and the speed at which the obstacle approaches can be considered. k2 is also a constant, and the second term of Formula 11 is based on the idea that the strength of the brake is defined according to the relative speed with the obstacle. In other words, the vehicle is braked and decelerated in a state where the relative speed with the obstacle is high and the obstacle is approaching, or the moving housing is approaching the obstacle. In Formula 11, the first term for generating the braking force according to the distance and the second term for generating the braking force according to the relative speed are added to define the brake strength. The relative speed is defined as positive when the mutual distance is reduced, and negative when the mutual distance is increased. In the negative case, the relative speed may be replaced with zero. By applying the replacement to zero or zero, the strength of the brake by the relative speed may be adjusted. In addition to the relative speed, a constant may be applied to the absolute speed of the moving housing or the absolute speed of the obstacle to add to the braking force.

  By defining the strength of the brake in consideration of not only the distance to the obstacle but also the relative speed, even obstacles at the same distance can effectively decelerate against the approaching obstacle, and contact Accident avoidance and damage reduction can be expected, so a safer mobile housing can be realized.

  The following operation mode will be described with reference to FIG. The following operation mode is a function of following other mobile cases or pedestrians to be followed after specifying the position with a sensing device. FIG. 14 is an example of sensing data when there are two pedestrians in the detection area 132 that the sensing device 131 can detect. Reference numerals 141 and 142 denote pedestrian data, which follow the pedestrian 141 as a tracking target. Specifically, the tracking target is tracked by controlling the rotational speed and translation speed of the movable casing. For example, the rotation speed can be controlled so that the object to be tracked is in front of the movable housing. Also, when compromising, depending on the distance to the subject to be obeyed, the speed will be faster if it is far from the subject to be followed, and the tracking speed will be determined so as to keep the distance to the subject to follow constant when approaching the subject to be followed Can do. By detecting the pedestrian 142 and various obstacles other than the tracking target with the sensing device in the same manner, a configuration in which the tracking target can be tracked while avoiding the obstacle is provided.

  In the tracking operation mode, in the present invention, the start of tracking and the tracking target can be selected by the multidimensional input device. The tracking target can be set and the tracking can be started from the state where both the moving housing and the tracking target are stopped. Further, it may be configured such that when the tracking target is moving, the pilot can control the tracking target to a position where the tracking target can be tracked, and can start tracking from there. Furthermore, it may be configured such that the follow-up operation form is temporarily stopped or stopped (finished) by operating the lever 31 in the middle of the follow-up action form, and then the operation by the operator or another operation form is made. At this time, the range setting and the operation content may be defined by the movement mode described above. Specifically, by assigning the area 151 in FIG. 15 as the dead zone, the area 152 as the start, and the area 153 as the pause or stop (end), an instruction input similar to the normal operation mode by the operator's operation is realized. be able to. Further, the shape of these areas is not limited to a circular shape or a sector shape, and the positional relationship can be arbitrarily set. Further, the neutral mode described above may be used in combination.

  The semi-autonomous operation mode will be described with reference to FIG. The semi-autonomous operation mode is a function that allows the movable housing to move safely and appropriately even without a pilot operation by the operator. As a sensing device, not only a laser distance sensor but also a camera, an ultrasonic sensor, a millimeter wave radar, a GPS, or the like that can acquire a distance or an image may be used. As in the prior art, for example, when the movement path of the movable casing is predetermined, a line, a magnetic tape, a plurality of RFIDs, etc. are arranged on the predetermined movement path, and the line sensor or magnetic By providing the sensor and the RFID reader, it can be configured to travel along a predetermined route. In addition, a map of the travel route is stored in advance, the route to the destination instructed by the driver is automatically generated, and then the sensor data such as the laser distance sensor is collated with the mark information shown on the map. To reach the destination without leaving the route. The laser distance sensor can be used not only for comparing environmental information with a map but also for detecting an obstacle. As with the follow-up operation mode, it may be configured to avoid obstacles on the route and realize safe autonomous driving while traveling along the movement route, or to avoid obstacles on the route temporarily by the operator Or you may make it the structure which transfers to another operation form, and you may make it the structure which returns to a follow-up action form again.

  In particular, the present invention provides a control interface that allows both piloting and autonomous driving to coexist. This is a control interface that continues traveling by the operation of the driver when the driver indicates the target direction and route while the vehicle is traveling autonomously or when an obstacle that cannot be avoided by dead ends or autonomous driving is encountered. First, at the start of the semi-autonomous operation mode, the driver can instruct the direction, route, or travel start aimed by the moving housing using the multidimensional input device. The moving housing is directed in the instructed direction, route, or previously directed direction, and starts traveling along a road while avoiding obstacles. In FIG. 16, the moving casing 161 at the start position of the semi-autonomous movement is given an instruction to move upward in FIG. 16, and performs autonomous traveling along the road in the upward direction. When autonomously traveling, as described above, for example, a traveling environment is recognized by a laser distance sensor, and the vehicle travels along a road based on data such as a road surface, a wall surface, a point marker or a line marker on the road surface. In some sensing devices including a laser distance sensor, a guide made of a retroreflective tape or a retroreflective coating can be used as mark information. When there are other pedestrians 164 or the like, the vehicle travels while avoiding the pedestrians 164 in an area where it can travel at a reduced speed. If it is determined that it cannot be avoided, stop. While traveling along the road, the user does not need to steer in particular, but when the moving housing stops due to an obstacle or the like, the user temporarily operates semi-autonomously by operating the steering lever 31. The operation mode is canceled, and the operation mode is changed to a direct operation mode. After avoiding the obstacle, it is possible to return to the semi-autonomous operation mode again by operating the multidimensional input device. Further, the semi-autonomous operation mode may be temporarily stopped or stopped (terminated) by operating the lever 31 in the middle of the semi-autonomous operation mode, and the operation may be shifted to a direct operation by the operator or another operation mode. However, it may be configured to return to the semi-autonomous operation mode again.

  Furthermore, when the road or passage approaches a branch or intersection in a semi-autonomous operation mode, the mobile housing determines from the sensing data and the map or route information that it is a branch before notifying the operator. To do. For example, in FIG. 16, it can be determined that the road is branched at the position of the movable casing 163. The operator uses the lever 31 to instruct the moving casing in the direction to proceed at the branch or intersection, and the moving casing continues to travel in the semi-autonomous mode again on the road in the indicated direction. In the example of FIG. 16, the driver selects the direction 165 or 166 using the lever 31 of the joystick, and then continues traveling on the road in the semi-autonomous operation mode.

  At this time, the range setting and the operation content may be defined by the movement mode described above. Specifically, the area 171 in FIG. 17 is a dead zone, the area 172 is started, the area 173 is paused or stopped (terminated), the direction 166 is selected as the area 174, and the direction 165 is selected as the area 175. It is possible to realize an instruction input similar to a normal operation mode by a user's operation. Alternatively, the area 166 may be allocated to the selection of the direction 166 so that not only the T-junction but also a crossroad can be selected. Further, the shape of these areas is not limited to a circular shape or a sector shape, and the positional relationship can be arbitrarily set. Further, the neutral mode described above may be used in combination.

  In the follow-up operation mode and the semi-autonomous operation mode, when these operation modes cannot be continued, the driver may be notified and then automatically moved to the pilot operation. For example, when the follow-up target is lost in the follow-up action form or the mark information is interrupted in the semi-autonomous action form, the operator is notified by a warning sound or a display on the buzzer. Upon receiving the notification, the pilot can continue to move by manual maneuvering, or can perform an operation for returning to the following operation mode or the semi-autonomous operation mode. In these operation modes, the multi-dimensional input device is used for switching the movement mode, and the movement mode is a single movement operation of the movable housing for any operation coordinate input within the operation coordinate range. It is.

  With this configuration, the present invention makes it possible to provide a control interface that is flexible and easy to maneuver by making the maneuvering by the operator coexist with the semi-autonomous operation mode of the moving housing.

In particular, a configuration of a system necessary for implementing each operation mode will be described in detail with reference to FIG. FIG. 18 shows the arithmetic device 7 described in FIG. 4 in more detail. The arithmetic device according to the present invention includes a relay controller 180 and a host system 185. The relay controller 180 transmits information related to the state of the moving housing such as a steering signal to the host system 185, and receives each command signal from the host system. Based on this, the information transmitted to the driver device 8 is modified to have a function of switching between driving of the prime mover by operating the joystick 3 and driving of the prime mover according to each operation mode. In FIG. 18, the control signal of the joystick 3 used as a multi-dimensional input device is input to the relay controller 180, the target command signal of the electric motor is transmitted from the relay controller 180 to the driver device 8, and the driver device 8 supplies the electric motor with current. It is configured to drive by flowing. In the relay controller 180, a switching unit 182 is provided, and a signal output as a final steering signal by the switching unit 182 is switched between a steering signal of the joystick 3 and a steering signal from the movement mode calculation unit 184. ing. When this switching means 182 adopts the control signal of the joystick 3, the control signal from the operator is output as a target command to the driver device 8 as it is, and when the control signal according to each of the above movement modes is adopted, for example, the movement mode Then, after being replaced / modified based on a forward / reverse mode, and also a control signal to which the speed limit or each operation mode is applied, it is output to the driver device 8 as a target command. The host system 185 is a system that mainly performs processing calculation in a safe maneuvering mode, a follow-up mode, and a semi-autonomous mode. The sensing device, GPS, and the like are input to the host system 185, and the host system 185 manages the map reference function and the route generation function. The host system 185 communicates with the relay controller 180 and the like, for example, receives information related to the state of the moving housing such as a control signal of the joystick 3 through the communication path 186 of the relay controller, and each command signal is transmitted through the communication path 187. Send to relay controller. The switching unit 182 may be implemented by a switch on the circuit, or may be implemented on the software of the relay controller. Alternatively, even if the switching unit 182 is omitted and the movement mode calculation unit 184 determines whether or not the steering signal is modified, the same function can be realized. It may be configured to switch according to a request from the host system or other input from the operator. Each speed mode may be installed in either the relay controller 180 or the driver device 8. By adopting such a configuration, it is possible to realize a control interface controller configuration that is flexible and easy to steer by allowing the pilot to operate and travel according to each operation mode coexist.
Of course, the present invention is not limited to these examples.

It is the whole external appearance of Example 1 of the present invention. It is a front view of Example 1 of the present invention. It is a side view of Example 1 of the present invention. It is a system configuration figure of Example 1 of the present invention. It is an external appearance of the joystick of Example 1 of this invention. It is the figure which looked at the joystick of Example 1 of this invention from the top. It is an example of the operation coordinate on the multidimensional space of Example 1 of this invention. It is an example of the coordinate area which selects the movement mode of Example 1 of this invention. It is an example of the coordinate area in the advance mode of Example 1 of this invention. It is an example of the coordinate area in the retreat mode of Example 1 of this invention. It is an example of the relationship between the y-axis of the operation coordinate in Example 1 of this invention, and target rotational speed. It is an example of the speed restriction | limiting in Example 1 of this invention. It is an example of the sensing data in the safe operation form of Example 1 of this invention. It is an example of the sensing data in the following operation | movement form of Example 1 of this invention. It is an example of the coordinate area in the following operation | movement form of Example 1 of this invention. It is an operation example in the semiautonomous movement vertical form of Example 1 of this invention. It is an example of the coordinate area in the semi-autonomous movement vertical form of Example 1 of this invention. It is an example of a structure of the relay controller of Example 1 of this invention. It is an example of the structure of the operation | movement form and movement mode of Example 1 of this invention.

DESCRIPTION OF SYMBOLS 1 Mobile housing | casing 20 Motor | power_engine 21 Driving wheel 22 Auxiliary wheel 3 Joystick 4 Sensing device 5 Seat 7 Calculation apparatus 8 Motor | power_engine driver apparatus

Claims (10)

Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,
The moving housing includes a multidimensional input device and a plurality of moving modes,
In the multidimensional input device, an operation state is input as operation coordinates on a multidimensional space,
A corresponding operation coordinate range is set in each of the plurality of movement modes,
The multi-dimensional input device is used for switching the movement mode, and the movement mode changes the movement casing to a different movement operation for any operation coordinate input, or the movement mode is within the operation coordinate range. A movable housing control interface or a movable housing provided with the control interface, wherein the movable housing is moved into a single moving operation in any of the operation coordinate inputs. The control interface according to claim 1,
In the operation mode for direct operation of the movable housing by the multidimensional input device, coordinate ranges are set so that a plurality of predetermined coordinate ranges correspond to the respective movement modes on the multidimensional space,
Even when any of the movement modes is applied to the movable casing, the neutral mode is applied to the movable casing when the operation coordinates of the multidimensional input device are within a predetermined coordinate range.
When the neutral mode is applied to the moving case, and the operation coordinates of the multidimensional input device are in a coordinate range corresponding to any of the moving modes, the corresponding moving mode is set to the moving case. A control interface of a mobile casing, which is applied to a body, or a mobile casing provided with the control interface. The control interface according to claim 2,
As the plurality of movement modes, there are a forward mode for performing forward movement, a curve and a turn on the spot, and a reverse mode for performing backward movement.
In the retraction mode, the operation coordinates of the multi-dimensional input device are reversed in the left-right direction and used as operation coordinates,
Alternatively, in the backward mode, the operation coordinates of the multidimensional input device are used as operation coordinates without being reversed in the left-right direction,
Alternatively, in the backward mode, the left-right direction of the operation coordinates of the multidimensional input device is used as the operation coordinates as a zero value,
Alternatively, the operation range by in-situ turning can be expanded by disabling the reverse mode and the neutral mode and setting the value to zero in the front-rear direction when the operation coordinate range of the original reverse operation is input in the forward mode. A control interface for a mobile casing, or a mobile casing provided with the control interface, comprising any one or a plurality of the control interfaces. The control interface according to claim 1,
In a follow-up operation mode that includes a sensing unit that senses a tracking target and moves so as to maintain a positional relationship with another moving object or a pedestrian based on sensing data from the sensing unit, a plurality of predetermined values are provided on the multidimensional space. The coordinate range is set so that the coordinate range corresponds to each of the movement modes,
A moving housing having a steering interface of the moving housing or the control interface having at least a start of a follow-up operation, an end of the follow-up operation, or a pause as the movement mode. The control interface according to claim 1,
In a semi-autonomous operation mode comprising a sensing means for recognizing an external environment, and the moving housing moves from an arbitrary point to another arbitrary point based on arbitrary landmark information based on sensing data by the sensing means, the multidimensional Coordinate ranges are set so that a plurality of predetermined coordinate ranges on the space correspond to the respective movement modes,
When the movement mode has at least a start of semi-autonomous operation, an end of semi-autonomous operation, or a temporary stop, and there is a branch in a route from the arbitrary point to another arbitrary point, the movement of the moving case A moving case having a steering interface of the moving case or a control interface having a moving mode for direction indication and route selection. Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,
The movable housing is
A multi-dimensional input device for operating the movable housing, wherein the operation state of the multi-dimensional input device is input as operation coordinates on a multi-dimensional space;
In the coordinate axes on the multi-dimensional space for determining the target speed of the movable casing or the prime mover, the relationship between the coordinate value of the operation coordinate on the coordinate axis and the target speed is a combination of nonlinear mathematical functions or discrete The rate of change of the target speed in a predetermined range where the absolute value of the coordinate value is small is smaller than the rate of change of the target speed in a predetermined range where the absolute value of the coordinate value is large. A control interface of a mobile casing to be moved, or a mobile casing having the control interface. Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,
The movable housing is
A multi-dimensional input device for operating the movable housing, wherein the operation state of the multi-dimensional input device is input as operation coordinates on a multi-dimensional space;
In the coordinate axes on the multi-dimensional space for determining the acceleration of the movable casing or the prime mover, the relationship between the coordinate values of the operation coordinates on the coordinate axes and the acceleration is a combination of arbitrary mathematical functions that are not constants, or discrete The acceleration in a predetermined range in which the absolute value of the coordinate value is small is smaller than the acceleration in a predetermined range in which the absolute value of the coordinate value is large, or the movable casing or the prime mover In the coordinate axes on the multi-dimensional space for determining the target speed, the relationship between the coordinate value of the operation coordinate on the coordinate axis and the target speed is not a linear function, but the minimum target speed in the specified time range is applied or every specified time. Apply the time delay function to increase the target speed to the target speed by applying either or both Control interface or the moving body having a control interface, the mobile housing and determining the or acceleration. Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,
The movable housing is
A multi-dimensional input device for operating the movable housing, and a selection input means for selecting a speed mode consisting of a plurality of stages,
The operation state of the multidimensional input device is input as operation coordinates on a multidimensional space, a restriction area is defined on the multidimensional space, and the operation coordinates included in the restriction area are stored in the restriction area. A control interface of a mobile housing characterized in that a target output is determined by applying a speed mode consisting of a plurality of steps based on the operation coordinates after conversion into a value not included, or the control interface A moving housing having. Two or more prime movers move by independently controlling forward and reverse rotation, and in a control interface for a moving housing that can move forward and backward, curve, and turn on the spot,
The movable housing is
A multi-dimensional input device for operating the movable housing, and a selection input means for selecting a speed mode consisting of a plurality of stages,
The operation state of the multi-dimensional input device is input as operation coordinates on a multi-dimensional space, and only when selecting a speed mode larger or smaller than any of the speed modes, not only the selection input means, A movable casing capable of selecting a speed mode larger or smaller than an arbitrary speed mode by operating an operation coordinate within a predetermined coordinate range or by operating a button or a touch panel in addition to the selection input unit. Control interface, or a mobile housing having the control interface. Two or more prime movers move by independently controlling forward rotation and reverse rotation, and in a movable casing that can move forward and backward, curve, and turn on the spot,
A motor control system, and a steering device system, wherein the steering device system and the motor control system can be controlled and moved by transmitting and receiving signals, a host control system, and a relay controller, The prime mover control system, the steering device system, and the host control system are connected via the relay controller, and the relay controller receives status information from the steering device system and the prime mover control system and receives the host information. Send to the control system, receive the command information from the host control system, based on this to send the command value that has been distributed and modified the information to the motor control system, or inside the relay controller It has the functions of a host control system or the host system Moving housing having a control interface or the control interface, the mobile housing, characterized in that it comprises the features of the relay controller within the system.

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