Patent Description:
A work vehicle disclosed in <CIT>, for example, includes a position detection unit ("receiving device" in the document) capable of obtaining position information pertaining to a machine body using a satellite positioning system, and a maneuvering control unit ("automatic maneuvering control unit" in the document) capable of performing maneuvering control such that the machine body follows a target heading on the basis of the position information obtained by the position detection unit. The target heading, which serves as a reference for automatic maneuvering control, is set on the basis of a position when an operating tool for registering a start point ("start point registration switch" in the document) is operated and a position when an operating tool for registering an end point ("end point registration switch" in the document) is operated.

Document <CIT> describes a work vehicle including a traveling vehicle body, a steering member for steering the traveling vehicle body, a position information acquiring device for acquiring position coordinates of the traveling vehicle body, an automatic straight traveling device for activating the steering member to move the traveling vehicle body straight ahead, a reference position acquiring member for acquiring traveling reference data serving as a reference for straight traveling of the traveling vehicle body, and a control device for controlling individual parts. Detection means for detecting a traveling state set as a state other than the straight traveling of the traveling vehicle body is provided, and the control device deletes the traveling reference data when the traveling state is detected by the detection means.

Document <CIT> describes an agricultural implement comprising: a traveling airframe capable of changing an automatic run by a manual steering and an automatic run for running by an automatic steering along a set running line set in parallel with a reference running line, a change-over switch capable of switching a manual run and an automatic run, and a starting point setting part for setting the plane position of the traveling airframe at the time point, when the change-over is performed by the change-over switch from the manual run to the automatic run, is set as a starting point of the set running line.

Document <CIT> describes a work vehicle equipped with a direction controlling means receiving and deciphering information about the position and time transmitted from the plurality of GPS satellites and correcting the traveling direction of the machine body based on the deciphered information about the position and time. The traveling controller is composed as follows. The work vehicle is previously subjected to teaching traveling. Thereby, the target traveling direction of the work vehicle is determined from the information about the position and time of the working vehicle obtained by an independent positioning method of the GPS. Traveling control is performed with the direction controlling means toward the target traveling direction during the automatic traveling of the work vehicle carried out subsequently to the teaching traveling. Document <CIT> describes a travel route generation device for a work vehicle working in a boundary-divided work field including: a starting point registration unit that position-registers a first endpoint on a boundary side of an entrance passage as a starting point; an intermediate point registration unit that position-registers shape feature points prescribing a work field shape as intermediate points; an end point registration unit that position-registers a second endpoint facing the first endpoint on a boundary side of the entrance passage as an end point; a basic shape calculation unit calculating a work field basic shape by connecting the starting point, intermediate points, and end point; and an entrance passage information generation unit that generates entrance passage information with a quadrangle as an entrance passage shape, the quadrangle having the starting point and end point as opposite vertices. Disclosure of the Invention Problems the Invention is to Solve.

According to the work vehicle disclosed in <CIT>, the start point and the end point are each registered using a separate dedicated operating tool. According to this configuration, when registering the start point and the end point, there is a risk of an occupant pressing the wrong operating tool, and in such a case, the operations for registering the start point and the end point are a burden for the occupant. If the operating tools serve as means for performing operations aside from setting the start point and the end point as well, the number of operating tools can be reduced, which is advantageous in terms of costs.

An object of the present invention is to provide a traveling work machine in which a start point and an end point can be set through simple operations when calculating a target heading.

Additional embodiments are defined by the dependent claims.

According to the present invention, both the start point and the end point can be set using a single operating tool. Accordingly, when registering the start point and the end point, the risk that an occupant will press the wrong operating tool is reduced, and the operations for registering the start point and the end point are easier, than when using a configuration in which separate operating tools are provided. Furthermore, using the single operating tool as a plurality of operating means reduces the number of operating tools and is therefore advantageous in terms of costs. This makes it possible to realize a traveling work machine in which a start point and an end point can be set through simple operations when calculating a target heading.

Moreover, according to the claimed invention, the machine body will always travel after the start point has been set, and the end point can be set in a different position from the start point. Furthermore, according to this configuration, the distance between the start point and the end point is at least a pre-set distance, and thus the target heading can be calculated with at least a predetermined accuracy.

Furthermore, according to the claimed invention, even if the occupant does not know how to set the target heading, they can set the start point and the end point while checking information displayed in the display unit. This makes it even easier to set the start point and the end point when calculating the target heading.

In the present invention, preferably, the target heading calculation unit is configured to be capable of setting the start point through an operation of the operating tool when an accuracy at which the position detection unit obtains the position information is at least a pre-set accuracy.

If the accuracy of the position information is poor when setting the start point and the end point, there is a risk that an accurate target heading cannot be calculated. According to this configuration, the start point cannot be set when the accuracy of the position information is poor, which averts the risk of maneuvering control being performed on the basis of an erroneous target heading.

In the present invention, preferably, the traveling work machine includes a maneuvering operation detection means that detects a maneuvering operation of the machine body, and when, after the start point has been set through an operation of the operating tool, a change amount of the maneuvering operation is detected as exceeding a pre-set range without the operating tool being operated, the setting of the start point is canceled.

When the travel trajectory is a turning state, the target heading cannot be calculated so as to follow the travel trajectory, and there is thus a risk that maneuvering control cannot be performed according to the occupant's intentions. According to this configuration, turning of the machine body can be determined on the basis of a change amount of the maneuvering operation, which averts a situation in which the start point and the end point are set in a state where the travel trajectory is turning.

In the present invention, preferably, the traveling work machine includes a cabin part occupied by an occupant, and a maneuvering tool which is supported by a support member in the cabin part and which is capable of performing a maneuvering operation of the travel apparatus, with the operating tool being disposed above the support member and directly below the maneuvering tool.

According to this configuration, the support member that supports the maneuvering tool also serves as a support member for the operating tool, and the operating tool can therefore be supported using a simple support configuration. This also makes it easy for the occupant to operate the operating tool while operating the maneuvering tool, making the operation for registering the start point and the end point even easier.

One embodiment of a traveling work machine according to the present invention will be described. <FIG> is a side view of a tractor serving as an example of the traveling work machine. In this tractor, a cabin part <NUM> is provided in a central part of a machine body <NUM>, which is supported by front wheels <NUM> and rear wheels <NUM> serving as a travel apparatus. A rotary tilling device <NUM>, which serves as a working device, is attached to a rear part of the machine body <NUM> via a hydraulic raising/lowering mechanism. The front wheels <NUM> function as maneuvering wheels, and a travel direction of the tractor is changed by changing a steering angle thereof. The steering angle of the front wheels <NUM> is changed by operating a steering mechanism <NUM>. A steering motor <NUM> for automatic maneuvering control is included in the steering mechanism <NUM>. A panel assembly <NUM> is provided in a front part of the interior of the cabin part <NUM>, and a steering wheel <NUM> serving as a maneuvering tool is disposed adjacent to the rear of the panel assembly <NUM>. Although not described in detail, a recessed area is provided at a central location, in the horizontal direction, in a rear part of the panel assembly <NUM>, and the recessed area is recessed further into the front of the machine body than left and right side parts of the panel assembly <NUM>. The steering wheel <NUM> is supported by a steering post <NUM> that serves as a support member, and a front part of the steering post <NUM> with respect to the machine body is located in the recessed area. During manual travel, maneuvering operations of the front wheels <NUM> are performed by a human operating the steering wheel <NUM>.

In the present invention, "maneuvering operations" includes changing the direction of the machine body <NUM> by changing the direction of the front wheels <NUM>, but if the travel apparatus is a crawler type, changing the direction of the machine body <NUM> using a speed difference between left and right crawlers is included in the "maneuvering operations".

As illustrated in <FIG>, a meter panel <NUM> and a side panel <NUM> are arranged vertically in the panel assembly <NUM>, and the side panel <NUM> is disposed higher than the meter panel <NUM>. Information pertaining to the driving of the machine body <NUM>, such as an engine speed, a remaining fuel amount, and so on, is displayed in the meter panel <NUM>. Guidance information for automatic maneuvering control, which will be described later, is displayed in the side panel <NUM>. The meter panel <NUM> and the side panel <NUM> are configured as part of a display unit <NUM> in terms of a configuration for the automatic maneuvering control.

A dial switch <NUM> is disposed on an upper surface of the steering post <NUM>. The side panel <NUM> can be operated by using the dial switch <NUM> as an operating tool, and the dial switch <NUM> is disposed in an upper part of the steering post <NUM> and directly below the steering wheel <NUM>. The dial switch <NUM> is configured to be freely rotatable about an axis extending in the up-down direction (or a direction inclined rearward in a front-back direction of the machine body), and an occupant can switch items of the guidance information displayed in the side panel <NUM> by rotating the dial switch <NUM>. Additionally, the dial switch <NUM> can be pressed in a downward direction (or a direction inclined forward in the front-back direction of the machine body). By pressing the dial switch <NUM>, the occupant can perform an operation for accepting a setting item, a selected item, or the like pertaining to the guidance information displayed in the side panel <NUM>. This dial switch <NUM> is also used as a trigger switch <NUM>, which will be described later on the basis of <FIG> and the like, and is operated as the trigger switch <NUM> by the occupant pressing the dial switch <NUM>. The dial switch <NUM> will be called the "trigger switch <NUM>" hereinafter.

A configuration for performing automatic maneuvering control will be described next. As illustrated in <FIG>, a control device <NUM> constituted by a large number of electronic control units (called "ECUs") is provided in the machine body <NUM>. The control device <NUM> is configured to be capable of switching a control mode to an automatic maneuvering mode in which automatic maneuvering control is executed, and a manual maneuvering mode in which automatic maneuvering control is not executed.

The machine body <NUM> is provided with a satellite positioning unit 8a, which measures the position of the machine body <NUM> using GPS (Global Positioning System), which is a well-known technology, as an example of a satellite positioning system (GNSS, or Global Navigation Satellite System) which detects the position of the machine body <NUM> by receiving radio waves from a satellite. Although the satellite positioning unit 8a uses DGPS (Differential GPS, a relative positioning method) in the present embodiment, it is also possible to use RTK-GPS (Real-Time Kinematic GPS, an interference-based positioning method).

Specifically, the satellite positioning unit 8a, which partially constitutes a position detection unit <NUM>, is provided in the machine body <NUM>, which is the subject of positioning. The satellite positioning unit 8a uses an antenna to receive radio waves emitted from a plurality of GPS satellites orbiting the earth. The position of the satellite positioning unit 8a is measured on the basis of information in the radio waves received from navigation satellites.

In addition to the satellite positioning unit 8a, the machine body <NUM> is provided with an inertial measurement unit 8b having, for example, an IMU (Inertial Measurement Unit), as a heading detection means that detects a heading of the machine body <NUM>. The inertial measurement unit 8b may be configured including a triaxial gyrosensor, a triaxial accelerometer, or the like. Although not illustrated, the inertial measurement unit 8b is provided in a low location at the center of the machine body <NUM> in a horizontal width direction, for example. The inertial measurement unit 8b can detect an angular velocity of a turning angle of the machine body <NUM>, and can calculate a change in the azimuth of the machine body <NUM> by integrating the angular velocity. Accordingly, heading information of the machine body <NUM> is included in measurement information measured by the inertial measurement unit 8b. Although not described in detail, in addition to the angular velocity of the turning angle of the machine body <NUM>, the inertial measurement unit 8b can also measure an angular velocity of a left-right tilt angle of the machine body <NUM>, a front-back tilt angle of the machine body <NUM>, and the like.

The control device <NUM> includes a route setting unit <NUM>, a heading deviation calculation unit <NUM>, a travel trajectory obtainment unit <NUM>, a control unit <NUM>, and a maneuvering control unit <NUM>. The route setting unit <NUM> sets a target travel route LM along which the machine body <NUM> is to travel (see <FIG>, <FIG>, and the like). The heading deviation calculation unit <NUM> is configured to be capable of calculating an angular deviation between a travel heading of the machine body <NUM> and a target heading LA, i.e., a heading deviation. On the basis of information of the heading deviation, the control unit <NUM> calculates and outputs an operation amount such that the machine body <NUM> travels along the target travel route LM. Besides the information of the heading deviation, the control unit <NUM> can calculate and output the operation amount on the basis of the position information of the machine body <NUM> measured by the satellite positioning unit 8a and the heading information of the machine body <NUM> measured by the inertial measurement unit 8b. The maneuvering control unit <NUM> controls the steering motor <NUM> on the basis of the operation amount. Note that the control unit <NUM> and the maneuvering control unit <NUM> may be configured in an integrated manner.

The trigger switch <NUM> is provided as an operating tool for setting the target travel route LM used in the automatic maneuvering control (see <FIG>, <FIG>, and the like) and starting the automatic maneuvering control. Although details will be given later, the target travel route LM is set on the basis of the target heading LA (see <FIG>), and the target heading LA is calculated on the basis of a travel trajectory along which the machine body <NUM> has traveled in the field in advance. A start position Ts (see <FIG>) and an end position Tf (see <FIG>) are set by operating the trigger switch <NUM> in travel performed to obtain the travel trajectory. Note that the trigger switch <NUM> need not be constituted by a single switch, and may instead be configured such that a switch for setting the start position Ts and a switch for setting the end position Tf are arranged side-by-side.

Information from the satellite positioning unit 8a, the inertial measurement unit 8b, the trigger switch <NUM> serving as an operating tool, a steering angle sensor <NUM> serving as a maneuvering operation detection means, a torque sensor <NUM>, a vehicle speed sensor <NUM>, an obstruction detection unit <NUM>, and the like is input to the control device <NUM>. The vehicle speed sensor <NUM> is configured to be capable of detecting the vehicle speed from the rotational speed of a transmission shaft in a transmission mechanism for the rear wheels <NUM>. Note that the vehicle speed may be detected not only by the vehicle speed sensor <NUM>, but also using a positioning signal of the satellite positioning unit 8a. The obstruction detection unit <NUM> is provided on both a front part and left and right side parts of the machine body <NUM>, and is configured to be capable of detecting a ridge of the field, metal poles in the field, and so on using an electro-optical rangefinding sensor, an image sensor, or the like, for example. When an obstruction is detected by the obstruction detection unit <NUM>, an alert is issued to the occupant using an alerting unit <NUM>, which uses a buzzer, audio guidance, or the like, for example. The control device <NUM> is also connected to a reporting unit <NUM>, and the reporting unit <NUM> is configured to report on states such as the vehicle speed, the engine speed, and the like, for example. The reporting unit <NUM> is configured to be displayed in the display unit <NUM>, for example. Furthermore, the alerting unit <NUM> may be configured to display the alert in the display unit <NUM> via the reporting unit <NUM>. In this case, an alert that a ridge has been detected, for example, is displayed in the display unit <NUM>. The alerting unit <NUM> may also be configured as part of the reporting unit <NUM>. The display unit <NUM> is configured to be capable of displaying, in a screen, a variety of information based on signal inputs from the reporting unit <NUM>, the alerting unit <NUM>, and the like. The display unit <NUM> is also configured to be capable of displaying various types of guidance information according to conditions of straight travel, conditions of turning travel, and the like of the machine body <NUM>.

The heading deviation calculation unit <NUM> calculates an angular deviation between a detected heading of the machine body <NUM>, detected by the satellite positioning unit 8a and the inertial measurement unit 8b, and a target heading LAin the target travel route LM, i.e., calculates the heading deviation. Then, when the control device <NUM> is set to the automatic maneuvering mode, the control unit <NUM> calculates and outputs an operation amount for controlling the steering motor <NUM> so as to reduce the angular deviation. In this manner, the maneuvering control unit <NUM> is configured to be capable of controlling the maneuvering of the machine body <NUM> so as to follow the target heading LA.

The travel trajectory obtainment unit <NUM> calculates a position of the machine body <NUM>, i.e., a host vehicle position NM, on the basis of the positioning signal measured by the satellite positioning unit 8a, the heading of the machine body <NUM> calculated by the heading deviation calculation unit <NUM>, and the vehicle speed detected by the vehicle speed sensor <NUM>. A storage unit <NUM> is configured to be capable of storing the host vehicle position NM as position information. The travel trajectory obtainment unit <NUM> stores the host vehicle position NM in the storage unit <NUM>, which is constituted by RAM (Random Access Memory), for example, as time passes. The travel trajectory obtainment unit <NUM> is also configured to be capable of obtaining a travel trajectory on the basis of an aggregation of host vehicle positions NM stored in the storage unit <NUM>. In sum, the travel trajectory obtainment unit <NUM> is configured to be capable of obtaining the travel trajectory of the machine body <NUM> on the basis of the detection, over time, of the host vehicle position NM serving as position information.

The operation amount is calculated by the control unit <NUM> on the basis of information on the heading deviation. The maneuvering control unit <NUM> executes the automatic maneuvering control on the basis of the operation amount calculated by the control unit <NUM> during the automatic maneuvering control of the machine body <NUM>. In other words, the steering motor <NUM> is operated such that the detection position of the machine body <NUM> as detected by the satellite positioning unit 8a and the inertial measurement unit 8b (the host vehicle position NM) is located on the target travel route LM.

In the present embodiment, the control signal may be the operation amount output by the control unit <NUM>, or may be a voltage value, a current value, or the like with which the maneuvering control unit <NUM> operates the steering motor <NUM>.

A reference route setting unit 76A, a target heading calculation unit 76B, and a target travel route setting unit 76C are included in the route setting unit <NUM>. As illustrated in <FIG>, a reference route corresponding to a target route for automatic maneuvering is set by the reference route setting unit 76A through reference route setting processing based on operations of the trigger switch <NUM>. The target heading calculation unit 76B calculates the target heading LA on the basis of a heading aligned with a lengthwise direction of the reference route. The target travel route setting unit 76C is configured to be capable of generating the target travel route LM following the target heading LA, using the reference route and the target heading LA as a reference. To generate the target travel route LM, a start position calculation unit 76D, an end determination unit 76E, and a distance calculation unit 76F are included in the route setting unit <NUM>. The start position calculation unit 76D, the end determination unit 76E, and the distance calculation unit 76F will be described later. Note that the reference route setting unit 76A and the target heading calculation unit 76B may be configured in an integrated manner.

<FIG> schematically illustrates an example of tilling work performed by the tractor. In this tilling work, work travel, in which the tractor moves forward along a linear work route while performing actual tilling work, and turning travel, in which the tractor turns to move to the next linear work route, are alternately and repeatedly performed multiple times. At this time, the first linear work route is a reference route which is steered manually, and the following linear routes are set in sequence by the route setting unit <NUM> so as to be arranged side-by-side along the reference route. These routes correspond to the target travel route LM for automatic maneuvering control, and a plurality of target travel routes LM1 to LM6 are indicated in <FIG>. Work travel involving automatic maneuvering control is performed in each of the target travel routes LM1 to LM6. When traveling between each of the target travel routes LM1 to LM6, the machine body <NUM> moves from an end position Lf of the work travel to a start position Ls of the next work travel in an unworked part of the field while reversing in the opposite direction from the travel direction of the work travel.

First, the reference route is generated. The occupant manually moves the machine body <NUM> to a ridge at one corner within the field. When the machine body <NUM> reaches the ridge at the corner, the occupant operates the trigger switch <NUM>. The position at the time when the occupant operates the trigger switch <NUM> is registered as the start position Ts by the reference route setting unit 76A. After the registration of the start position Ts, the occupant performs manual operations to move the machine body <NUM> straight (or substantially straight) from the start position Ts along the ridge on one side of the field. During this period, the host vehicle position NM is calculated by the travel trajectory obtainment unit <NUM> as time passes and is stored in the storage unit <NUM>. Then, after the machine body <NUM> has moved straight (or substantially straight) from one end to the other end of the ridge on the one side, the occupant stops the machine body <NUM> and operates the trigger switch <NUM> again. The position at the time when the occupant operates the trigger switch <NUM> again is registered as the end position Tf by the reference route setting unit 76A. The travel trajectory obtainment unit <NUM> obtains the travel trajectory on the basis of an aggregate of the host vehicle positions NM between the start position Ts and the end position Tf, and the reference route setting unit 76A calculates the reference route between the start position Ts and the end position Tf on the basis of that travel trajectory. When the machine body <NUM> travels along the target travel route LM, the direction which follows the reference route becomes the target heading LA.

Note that the travel of the machine body <NUM> from the start position Ts to the end position Tf may be work travel involving tilling work, or may be travel in a non-work state. When positional coordinates of the reference route are set, automatic maneuvering control can be performed in at least part of the reference route.

After the setting of the reference route is complete, the occupant moves the machine body <NUM> to the start position Ls in a target region for the first work travel in the field. In the embodiment illustrated in <FIG>, the target region for the first work travel is adjacent to the reference route, and thus the occupant performs turning travel for reversing the travel direction of the machine body <NUM> by <NUM> degrees in order to move the machine body <NUM> to the start position Ls. At this time, the control unit <NUM> can determine that the machine body <NUM> has turned due to the heading of the machine body <NUM> being reversed. The heading of the machine body <NUM> reversing can be detected by the satellite positioning unit 8a, the inertial measurement unit 8b, or the like. Aside from the heading of the machine body <NUM> reversing, the turning of the machine body <NUM> may be determined by operations of various devices. As the operations of various devices, for example, a PTO shaft clutch may be configured to be manipulated in and out. Additionally, the machine body <NUM> reaching the start position Ls may be determined by the satellite positioning unit 8a.

After this turning travel is complete, the manual maneuvering mode of the control device <NUM> is continued, and the occupant causes the machine body <NUM> to travel along the target heading LA through manual operations. During this period, the control device <NUM> confirms determination conditions for the heading deviation of the machine body <NUM> calculated by the heading deviation calculation unit <NUM>, the direction of the front wheels <NUM>, the steering angle of the steering wheel <NUM>, and the like, and determines whether or not the state of the machine body <NUM> is a state suitable for the next tilling work. Whether or not the state of the machine body <NUM> is suitable for tilling work is determined, for example, using a position distanced from the pre-turning travel position by an integral multiple of a work width in a direction orthogonal to the target heading LA as a reference position, and is determined on the basis of whether or not travel misalignment with respect to the reference position in the left-right direction of the machine body <NUM> is within a permissible range. If the travel misalignment is outside of the permissible range, the occupant manually steers the machine body <NUM> so that the travel misalignment of the machine body <NUM> enters the permissible range.

The heading deviation of the machine body <NUM> with respect to the target heading LA being significantly high, the steering wheel <NUM> being repeatedly steered to the left and right so that the position of the steering wheel <NUM> fails to stabilize, the vehicle speed of the machine body <NUM> being too fast or too slow, and so on can be given as examples of states not suitable for tilling work. The detection accuracy of the position detection unit <NUM> being lower than a pre-set threshold can also be given as an example of a state not suitable for tilling work.

When the control device <NUM> determines that the state of the machine body <NUM> is a state suitable for the next tilling work, the automatic maneuvering control can be performed by operating the trigger switch <NUM>. In other words, the target travel route LM1 is set by the target travel route setting unit 76C, and the work travel is started, in response to the occupant operating the trigger switch <NUM>. When the work travel is started, the automatic maneuvering control is performed so that the machine body <NUM> travels along the target travel route LM1. The target travel route LM1 is a target travel route LM which is set to a heading that follows the target heading LA, and in which the machine body <NUM> performs the first work travel after the setting of the reference route. While the automatic maneuvering control is performed, automatic steering is performed through operations by the steering mechanism <NUM>, and the vehicle speed of the machine body <NUM> is also automatically adjusted. Note, however, that the configuration may be such that the vehicle speed of the machine body <NUM> can be adjusted through human operations made by the occupant even while automatic maneuvering control is being performed.

When the automatic maneuvering control performed along the target travel route LM1 ends, the occupant continues manual steering until, through the above-described turning travel, the state of the machine body <NUM> becomes a state suitable for the next tilling work. If the trigger switch <NUM> is permitted to be operated, the occupant operates the trigger switch <NUM>, and the target travel route setting unit 76C sets the target travel route LM2 for the next time to a heading following the target heading LA. Then, the automatic maneuvering control is performed so that the machine body <NUM> travels along the target travel route LM2. Thereafter, the turning travel, the setting of the target travel route LM, and the work travel are repeated through the above-described process, in order of the target travel routes LM3, LM4, LM5, and LM6.

The display of guidance information pertaining to reference route generation will be described on the basis of <FIG>, <FIG>, and <FIG>. The reference route setting unit 76A generates the reference route on the basis of the flowchart illustrated in <FIG>. Before the generation of the reference route, the route setting unit <NUM> determines whether or not the position information of the machine body <NUM> can be detected by the position detection unit <NUM> (step #<NUM>). If the position information of the machine body <NUM> is not detected (step #<NUM>: No), a message indicating that the detection is not possible is displayed in the display unit <NUM> (step #<NUM>), and the reference route is not generated. In this manner, when the accuracy of the obtainment of the position information by the position detection unit <NUM> is at least a pre-set accuracy, the reference route setting unit 76A can set the start position Ts through an operation of the trigger switch <NUM>, which serves as an operating tool.

If the position information of the machine body <NUM> is detected (step #<NUM>: Yes), guidance information for the start position Ts, such as that indicated by <NUM>-Ain <FIG>, is displayed in the display unit <NUM> (step #<NUM>), and the start position Ts can be registered. The guidance information indicated by <NUM>-A, <NUM>-B, and <NUM>-C in <FIG> are displayed in the side panel <NUM> illustrated in <FIG>. Note, however, that the guidance information may be displayed in the meter panel <NUM> illustrated in <FIG>. In the guidance information for the start position Ts indicated by <NUM>-Ain <FIG>, the start position Ts is displayed as "start point A". A state where the guidance information for the start position Ts is displayed in the display unit <NUM> is a standby state for an operation of the trigger switch <NUM> (step #<NUM>). When the trigger switch <NUM> is operated (step #<NUM>: Yes), the reference route setting unit 76A registers the start position Ts (the start point A) (step #<NUM>).

After the registration of the start position Ts, the occupant moves the machine body <NUM> forward through manual operations. Then, the reference route setting unit 76A determines whether or not the machine body <NUM> has traveled at least a pre-set distance by calculating the distance between the start position Ts and the host vehicle positions NM as time passes (step #<NUM>). If the travel distance of the machine body <NUM> has not reached the set distance (step #<NUM>: No), guidance information indicating that the travel distance has not reached the set distance is displayed in the display unit <NUM>, even if the occupant operates the trigger switch <NUM>. As the guidance information indicating that the travel distance has not reached the set distance, for example, a message reading "insufficient forward travel distance" is displayed, as indicated by <NUM>-B in <FIG>. In this manner, the reference route setting unit 76A can, through an operation of the trigger switch <NUM>, set the end position Tf (an end point B) after the start position Ts (the start point A) has been set by the trigger switch <NUM> being operated as an operating tool and after the machine body <NUM> has traveled a pre-set distance following the setting of the start position Ts.

While the machine body <NUM> is moving forward as a result of the manual operations, the reference route setting unit 76A determines whether or not the machine body <NUM> is turning (step #<NUM>). A change amount in the maneuvering operations based on operation of the steering wheel <NUM> is detected by the steering angle sensor <NUM>. The configuration is such that the turning of the machine body <NUM> can be determined by detecting that the change amount in the maneuvering operations based on the detection by the steering angle sensor <NUM> has exceeded a pre-set range. Additionally, the heading deviation calculation unit <NUM> can calculate a turning heading of the machine body <NUM> on the basis of a positioning signal from the satellite positioning unit 8a, an inertia signal from the inertial measurement unit 8b, or the like. Then, when the reference route setting unit 76A determines that the machine body <NUM> is turning (step #<NUM>: Yes), the registration of the start position Ts is canceled and the generation of the reference route is aborted (step #<NUM>). At this time, guidance information indicating that the generation of the reference route has been aborted, e.g., a message reading "a turn has been detected and the generation of the reference route will end. Please generate the reference route again", is displayed in the display unit <NUM>. In this manner, when, after the start position Ts (the start point A) has been set by operating the trigger switch <NUM> as an operating tool, the change amount in the maneuvering operations is detected as having exceeded a pre-set without the trigger switch <NUM> being operated, the setting of the start position Ts is canceled.

If the travel distance of the machine body <NUM> has reached the set distance (step #<NUM>: Yes), guidance information for the end position Tf, such as that indicated by <NUM>-C in <FIG>, is displayed in the display unit <NUM> (step #<NUM>), and the end position Tf can then be registered. In the guidance information for the end position Tf indicated by <NUM>-C in <FIG>, the end position Tf is displayed as the "end point B". A state where the guidance information for the end position Tf is displayed in the display unit <NUM> is a standby state for an operation of the trigger switch <NUM> (step #<NUM>). In this manner, when the end position Tf (the end point B) can be set by operating the trigger switch <NUM> as an operating tool, the display unit <NUM> displays an indication that the end position Tf can be set.

When the trigger switch <NUM> is operated (step #<NUM>: Yes), the reference route setting unit 76A registers the end position Tf (step #<NUM>). The reference route is generated, and the target heading LA is calculated, through the foregoing steps. In this manner, the reference route setting unit 76A sets the reference route on the basis of the travel trajectory of the machine body <NUM>. Additionally, the trigger switch <NUM> serving as the operating tool is configured to be capable of setting both the start position Ts (the start point A) and the end position Tf (the end point B) when setting the reference route.

While waiting for the trigger switch <NUM> to be operated (step #<NUM>: No), the reference route setting unit 76A determines whether or not the machine body <NUM> is turning through the same method as in step #<NUM> (step #<NUM>). When it is determined that the machine body <NUM> is turning (step #<NUM>: Yes), as described above, the registration of the start position Ts is canceled and the generation of the reference route is aborted (step #<NUM>), and guidance information indicating that the generation of the reference route has been aborted is displayed in the display unit <NUM>.

The display of guidance information in turning travel will be described on the basis of <FIG> and <FIG>. As illustrated in <FIG>, when turning travel is performed after the completion of automatic maneuvering control along the target travel route LM, guidance information pertaining to the turning travel is displayed in the display unit <NUM>. The guidance information for a left turn, indicated by <NUM>-Ain <FIG> and <FIG>, is displayed in the display unit <NUM> after automatic travel control along the target travel route LM[n-<NUM>] has been performed. Additionally, the guidance information for a right turn, indicated by <NUM>-B in <FIG> and <FIG>, is displayed in the display unit <NUM> after automatic travel control along the target travel route LM[n] has been performed. A map screen showing the machine body <NUM> and the surroundings of the machine body <NUM> is included in this guidance information. Additionally, although this guidance information is displayed in the side panel <NUM> illustrated in <FIG>, the guidance information may be displayed in the meter panel <NUM> illustrated in the same drawing.

As illustrated in <FIG>, the start position calculation unit 76D, the end determination unit 76E, and the distance calculation unit 76F are included in the route setting unit <NUM>. <FIG> illustrates a flowchart pertaining to the display of the guidance information pertaining to the turning travel, and processing based on this flowchart is performed by the control device <NUM>.

The end determination unit 76E determines whether or not the automatic maneuvering control for traveling along the target travel route LM has ended (step #<NUM>). The end of the automatic maneuvering control is determined, for example, on the basis of whether or not a PTO clutch lever (not shown), a pumper lever (not shown), or the like has been operated. When the end determination unit 76E determines that the automatic maneuvering control has ended (step #<NUM>: Yes), the host vehicle position NM at the point in time of the determination that the automatic maneuvering control has ended is stored in the storage unit <NUM> as the end position Lf (step #<NUM>). The end position Lf is used as work travel position information WP through which the start position calculation unit 76D calculates the start position Ls2 of the next work travel. Note that of the end positions Lf illustrated in <FIG>, the end position Lf of the target travel route LM[n] is also indicated as the work travel position information WP for calculating the start position Ls2 of the next work travel. The present specification assumes that the start position Ls2 will be calculated thereafter by the start position calculation unit 76D, and is therefore described as being distinct from the start position Ls.

Information pertaining to the previous turning travel is stored in the storage unit <NUM>. The start position calculation unit 76D is configured to be capable of determining whether the previous turning travel was a right turn or a left turn by reading out data pertaining to the turning travel from the storage unit <NUM>. As illustrated in <FIG>, when the machine body <NUM> repeats the automatic maneuvering control along the target heading LA, the turning travel at the ridges of the field typically alternates between a right turn and a left turn. As such, the start position calculation unit 76D determines whether the previous turning travel was a right turn or a left turn (step #<NUM>). Note that the configuration may be such that the determination in step #<NUM> is performed by a module aside from the start position calculation unit 76D. When the previous turning travel was a right turn (step #<NUM>: right turn), the start position calculation unit 76D calculates the next start position Ls2 on a left turn side on the basis of the previous turning travel, before the machine body <NUM> starts the turn (step #<NUM>-<NUM>). Guidance information for a left turn is then displayed in the display unit <NUM> (step #<NUM>-<NUM>), and a display line L2 based on the start position Ls2 is also displayed in the guidance information. On the other hand, when the previous turning travel was a left turn (step #<NUM>: left turn), the start position calculation unit 76D calculates the next start position Ls2 on a right turn side on the basis of the previous turning travel, before the machine body <NUM> starts the turn (step #<NUM>-<NUM>). Guidance information for a right turn is then displayed in the display unit <NUM> (step #<NUM>-<NUM>), and a display line L2 based on the start position Ls2 is also displayed in the guidance information.

In this manner, when the end determination unit 76E determines that the work travel has ended, the start position calculation unit 76D calculates the start position Ls2 on the right or the left of the travel direction of the machine body <NUM> in the work travel on the basis of the work travel position information WP serving as position information, and the display unit <NUM> displays guidance information for guiding the turning travel to the start position Ls2. At this time, when the start position Ls has been calculated in one of the left- or right-side turn directions with respect to the travel direction in the previous turning travel, the start position calculation unit 76D calculates the start position Ls2 in the other of the left- or right-side turn directions relative to the travel direction in the current turning travel, and the display unit <NUM> displays the display line L2, based on the start position Ls2, further on the other of the left and right sides than the machine body <NUM> in the map screen.

After the guidance information has been displayed in the display unit <NUM> through the process of step #<NUM>-<NUM> or step #<NUM>-<NUM>, the occupant turns the machine body <NUM> by operating the steering wheel <NUM>. The control device <NUM> is configured so that the turn direction at this time can be determined by the steering angle sensor <NUM> serving as a maneuvering operation detection means (step #<NUM>-<NUM>, step#<NUM>-<NUM>). Note that the means for determining the turn direction is not limited to a determination made by the steering angle sensor <NUM>, and may be, for example, a determination based on an aggregation of the position information of the machine body <NUM> measured by the satellite positioning unit 8a, a determination based on the heading information of the machine body <NUM> measured by the inertial measurement unit 8b, or the like. In other words, the maneuvering operation detection means may be a configuration in which the maneuvering operations is detected by, for example, the satellite positioning unit 8a or the inertial measurement unit 8b detecting a turn.

If the actual turn direction of the machine body <NUM> differs from the guidance information displayed in the display unit <NUM>, the guidance information displayed in the display unit <NUM> is changed to guidance information which corresponds to the actual turn direction of the machine body <NUM>. When the actual turn direction of the machine body <NUM> is a left turn (step#<NUM>-<NUM>: left turn) in a state where guidance information for a right turn is displayed in the display unit <NUM> (step #<NUM>-<NUM>), the start position calculation unit 76D calculates the next start position Ls2 on the left turn side (step #<NUM>-<NUM>). Then, the guidance information in the display unit <NUM> is changed to guidance information for a left turn (step #<NUM>-<NUM>). On the other hand, when the actual turn direction of the machine body <NUM> is a right turn (step#<NUM>-<NUM>: right turn) in a state where guidance information for a left turn is displayed in the display unit <NUM> (step #<NUM>-<NUM>), the start position calculation unit 76D calculates the next start position Ls2 on the right turn side (step #<NUM>-<NUM>). Then, the guidance information in the display unit <NUM> is changed to guidance information for a right turn (step #<NUM>-<NUM>). In this manner, when, in turning travel, the steering wheel <NUM> (the maneuvering tool) is operated in the turn direction to the side opposite from the side on which the start position calculation unit 76D has calculated the start position Ls2, the start position calculation unit 76D re-calculates the start position Ls2 in the turn direction on the side toward which the steering wheel <NUM> has been operated, and the display unit <NUM> re-displays the start position Ls2 in the map screen, further than the machine body <NUM> toward the side corresponding to the turn direction in which the steering wheel <NUM> has been operated.

Before describing step #<NUM> and on, a method by which the start position calculation unit 76D calculates the start position Ls2 will be described. In the embodiment illustrated in <FIG>, after the automatic travel control is performed along the target travel route LM[n], the host vehicle position NM at the point in time when the end of the automatic maneuvering control was determined is stored in the storage unit <NUM> as the end position Lf of the target travel route LM[n] (the work travel position information WP) on the basis of step #<NUM> in <FIG>. Before the automatic maneuvering control in the target travel route LM[n], a left turn is made from the end position Lf of the target travel route LM[n-<NUM>] to the start position Ls of the target travel route LM[n]. Accordingly, a right turn is determined in step #<NUM> of <FIG> before the machine body <NUM> turns from the end position Lf of the target travel route LM[n], i.e., the work travel position information WP.

In the embodiment illustrated in <FIG>, the end position Lf of the target travel route LM[n-<NUM>] and the start position Ls of the target travel route LM[n] are separated by a first separation distance P1. An area of work travel based on the target travel route LM[n-<NUM>] and an area of work travel based on the target travel route LM[n] are areas which are adjacent to each other. Based on this, the first separation distance P1 is a distance equivalent to the work width of the tilling device <NUM> attached to the tractor via a PTO shaft, or a distance around ten percent smaller than the work width of the tilling device <NUM>, for example. In <FIG> and <FIG> too, which will be described later, the first separation distance P1 is as described on the basis of <FIG>. When the first separation distance P1 is a distance smaller than the work width of the tilling device <NUM>, the work width of the work travel based on the target travel route LM[n-<NUM>] and the work width of the work travel based on the target travel route LM[n] overlap by a predetermined width (less than ten percent of the work width, for example).

The end position Lf of the target travel route LM[n-<NUM>] is a position where the previous turning travel was started. The start position Ls of the target travel route LM[n] is a position where the previous turning travel ended. Furthermore, the end position Lf of the target travel route LM[n-<NUM>] and the start position Ls of the target travel route LM[n] are separated by the first separation distance P1. Based on this, the start position calculation unit 76D estimates that the next automatic maneuvering control will be performed at a position separated from the target travel route LM[n] in the horizontal direction (a direction orthogonal to the target heading LA; the same applies hereinafter) by the first separation distance P1. The start position calculation unit 76D then calculates the start position Ls2 for new work travel on a side opposite to where the target travel route LM[n-<NUM>] is located, in the horizontal direction, with respect to the work travel position information WP, the start position Ls2 for new work travel being separated from the work travel position information WP by the first separation distance P1 (step #<NUM>-<NUM>). A target travel route LM[n+<NUM>] illustrated in <FIG> is a planned target travel route LM set after the machine body <NUM> has reached the start position Ls2.

Then, on the basis of the process of step #<NUM>-<NUM>, guidance information for the right turn indicated by <NUM>-B in <FIG> is displayed in the display unit <NUM> as the map screen. In this manner, the display unit <NUM> displays the surroundings of the machine body <NUM>, including the machine body <NUM>, as the map screen. The work travel position information WP and the start position Ls2 of the next work travel are displayed in this map screen as linear display lines L1 and L2, respectively, which follow the target heading LA.

In this manner, the start position calculation unit 76D calculates the start position Ls2 on the basis of the separation distance between the position where the previous turning travel started and the position where the previous turning travel ended, and the display unit <NUM> displays the start position Ls2, calculated on the basis of the separation distance, in the guidance information.

As illustrated in <FIG> and <FIG>, a machine body symbol SY and a turning route indicated by a broken line are schematically indicated in the map screen in the guidance information displayed in the display unit <NUM>. While the machine body <NUM> is performing turning travel, the machine body symbol SY indicating the position of the machine body <NUM> moves along the turning route indicated by the broken line, as indicated in the guidance information for <NUM>-B and <NUM>-C in <FIG>. Although the display unit <NUM> displays the turning route of the turning travel in the map screen, the turning route is not set in advance in the present embodiment, and the turning route indicated by the broken line is displayed in the map screen as a guide for reaching the start position Ls2. The machine body symbol SY is displayed as a guide in any desired location on the turning route indicated by the broken line, on the basis of the host vehicle position NM calculated by the travel trajectory obtainment unit <NUM>. Additionally, the orientation of the machine body symbol SY changes in the map screen in the guidance information on the basis of a turning heading calculated by the heading deviation calculation unit <NUM> (see <FIG>).

Descriptions of the flowchart in <FIG> will now be resumed. The distance calculation unit 76F (see <FIG>) is configured to be capable of calculating the separation distance between the position information stored in the storage unit <NUM> and the position information based on the current position of the machine body <NUM>. While the machine body <NUM> is performing turning travel, the separation distance between the work travel position information WP and the host vehicle position NM is calculated by the distance calculation unit 76F as time passes (step #<NUM>). In other words, the distance calculation unit 76F calculates the separation distance using the position information from the point in time when the end determination unit 76E (see <FIG>) determines that the work travel has ended. The distance calculation unit 76F starts calculating the separation distance after the turning travel has started. Then, as indicated in the guidance information indicated by <NUM>-B and <NUM>-C in <FIG>, a separation distance display DF, which is a distance of a component of the separation distance which is orthogonal to the target heading LA, is displayed in the display unit <NUM> (step #<NUM>). In this manner, when the end determination unit 76E determines that the work travel has ended, the distance calculation unit 76F calculates the separation distance using, as the position information stored in the storage unit <NUM>, the work travel position information WP, which is position information based on the work travel determined by the end determination unit 76E to have ended. Furthermore, the display unit <NUM> is configured to be capable of displaying the work travel position information WP and the separation distance display DF. The display unit <NUM> starts displaying the separation distance after the turning travel has started.

While the machine body <NUM> is performing the turning travel, the control device <NUM> determines, on the basis of the position information of the machine body <NUM> measured by the satellite positioning unit 8a, whether or not the machine body <NUM> is turning to move further in the horizontal direction than the start position Ls2 of the next work travel (step #<NUM>). <FIG> illustrates a state in which, in the turning travel, the machine body <NUM> travels a distance greater than the first separation distance P1 from the work travel position information WP in the horizontal direction, and passes the start position Ls2 of the next work travel (indicated as a planned start position Ls2' in <FIG>). Although the planned start position Ls2' indicated in <FIG> was the start position Ls2 of the next work travel that was originally set, the planned start position Ls2' is not used as the start position Ls2 of the next work travel. In this case, a determination of Yes is made in step #<NUM> of <FIG>. When a determination of Yes is made in step #<NUM>, the start position calculation unit 76D calculates the start position Ls2 of a new work travel at a position separated from the planned start position Ls2' by the first separation distance P1 in the horizontal direction, on the side opposite from the side of the location of the work travel position information WP (step #<NUM>). A target travel route LM[n+<NUM>] illustrated in <FIG> is a planned target travel route LM set after the machine body <NUM> has reached the start position Ls2.

A second separation distance P2, which is a separation distance between the work travel position information WP and the start position Ls2 of the new work travel, is indicated in <FIG>. The second separation distance P2 is double the distance of the first separation distance P1. Based on this, an unworked part having a width equivalent to the work width of the tilling device <NUM> in the horizontal direction remains between the area of the work travel based on the target travel route LM[n] and the area of the work travel to be performed on the basis of the start position Ls2 of the new work travel. The width of the unworked part is a width over which tilling work can be performed between already-worked parts on both sides, without gaps, when performing the tilling work. In <FIG> and <FIG> too, which will be described later, the second separation distance P2 is as described on the basis of <FIG>.

Additionally, when the start position calculation unit 76D has calculated the start position Ls2 of the new work travel, the guidance information for a right turn, indicated by <NUM>-C in <FIG>, is displayed in the display unit <NUM> as a map screen, on the basis of the process of step #<NUM>. The work travel position information WP, the planned start position Ls2', and the start position Ls2 of the new work travel are displayed in the map screen indicated by <NUM>-C as linear display lines L1, L2', and L2, respectively, which follow the target heading LA. The display line L2' based on the planned start position Ls2' is located between the display line L1 based on the work travel position information WP and the display line L2' based on the start position Ls2 of the new work travel. Then, a turning route indicated by a broken line is displayed from the display line L1 based on the work travel position information WP to the display line L2' based on the start position Ls2 of the new work travel, as a guide for reaching the start position Ls2 of the new work travel. The display of the machine body symbol SY and the display of the separation distance display DF in the guidance information indicated by <NUM>-C in <FIG> are as already described on the basis of the guidance information indicated by <NUM>-B in the same drawing.

While the machine body <NUM> is performing turning travel, it is determined whether or not the heading deviation, calculated by the heading deviation calculation unit <NUM> (see <FIG>), between the turning heading of the machine body <NUM> and the target heading LA is within a pre-set permissible range (step #<NUM>). If the heading deviation is outside the permissible range (step #<NUM>: No), the determination process of step #<NUM>, and the processes of step #<NUM> and step #<NUM> performed when a determination of Yes is made in step #<NUM>, are repeated. When the heading deviation is within the permissible range (step #<NUM>: Yes), the distance between the work travel position information WP and the start position Ls2 of the next work travel is stored in the storage unit <NUM> (see <FIG>) (step #<NUM>), and the processing moves to the flowchart illustrated in <FIG>, which will be described later. Additionally, after the turning travel has ended, the display unit <NUM> ends the display of the separation distance display DF.

In the determination in step #<NUM>, whether or not a distance, in the horizontal direction, between the work travel position information WP and the host vehicle positions NM calculated by the travel trajectory obtainment unit <NUM> is within the range of a reference distance that takes the work width of the work travel as a reference may be added as a determination item. In this case, aside from the work width of the work travel, a value which is an integral multiple of the work width may be used as the reference distance, or a value obtained by subtracting the aforementioned overlap amount from the value which is an integral multiple of the work width may be used as the reference distance.

Additionally, the distance recorded in the storage unit <NUM> in step #<NUM> may be the actual distance between the work travel position information WP and the start position Ls2 of the next work travel, or may be a distance, among distances which are integral multiples of the reference distance which takes the work width of the work travel as a reference, that is close to the actual distance. In this manner, the distance stored in the storage unit <NUM> is, for example, the first separation distance P1, the second separation distance P2, or the like.

When the turning travel has been performed in such a manner that an unworked part having a width equivalent to the work width of the tilling device <NUM> in the horizontal direction remains between the work travel position information WP and the start position Ls2 of the next work travel (see <FIG>), guidance information such as that illustrated in <FIG> is displayed in the display unit <NUM> in the turning travel performed thereafter. The target travel route LM[n-<NUM>] in <FIG> may be thought of as being the same as the target travel route LM[n+<NUM>] set after the machine body <NUM> reaches the start position Ls2 in <FIG>.

In <FIG>, before the automatic maneuvering control in the target travel route LM[n], a left turn is made across the end position Lf of the target travel route LM[n-<NUM>] and the start position Ls of the target travel route LM[n]. The guidance information for a left turn, indicated by <NUM>-Ain <FIG> and <FIG>, is displayed in the display unit <NUM> after automatic travel control along the target travel route LM[n-<NUM>] has been performed. The guidance information for a right turn, indicated by <NUM>-B in <FIG> and <FIG>, is displayed in the display unit <NUM> on the basis of the process of step #<NUM>-<NUM> indicated in <FIG>, after the automatic travel control has been performed along the target travel route LM[n] and before the machine body <NUM> actually starts the turn. A map screen showing the machine body <NUM> and the surroundings of the machine body <NUM> is included in this guidance information. Additionally, although this guidance information is displayed in the side panel <NUM> illustrated in <FIG>, the guidance information may be displayed in the meter panel <NUM> illustrated in the same drawing.

The end position Lf of the target travel route LM[n-<NUM>] and the start position Ls of the target travel route LM[n] are separated by the second separation distance P2, and the second separation distance P2 has a distance of double (or substantially double but less than double) the work width of the tilling device <NUM>. Based on this, in <FIG>, an unworked part having a width equivalent to the work width of the tilling device <NUM> in the horizontal direction remains between the area of the work travel based on the target travel route LM[n-<NUM>] and the area of the work travel based on the target travel route LM[n], When tilling work is performed in this unworked part, the tilling work is performed, without gaps, between the area of the work travel based on the target travel route LM[n-<NUM>] and the area of the work travel based on the target travel route LM[n],.

In the embodiment illustrated in <FIG>, in the previous turning travel, the end position Lf of the target travel route LM[n-<NUM>] and the start position Ls of the target travel route LM[n] are separated by the second separation distance P2. Based on this, the start position calculation unit 76D estimates that the next automatic maneuvering control will be performed at a position separated from the target travel route LM[n] in the horizontal direction by the second separation distance P2. The start position calculation unit 76D then calculates the start position Ls2 for the next work travel at a position which is in the horizontal direction to the side opposite from the side on which the target travel route LM[n-<NUM>] is located, and which is separated from the work travel position information WP by the second separation distance P2. The target travel route LM[n+<NUM>] illustrated in <FIG> is a planned target travel route LM set after the machine body <NUM> has reached the start position Ls2.

The display line L1 based on the work travel position information WP and the display line L2' based on the start position Ls2 of the next work travel are displayed in the guidance information indicated by <NUM>-B in <FIG> and <FIG>. In the embodiment illustrated in <FIG>, an unworked part having a width equivalent to the work width of the tilling device <NUM> in the horizontal direction remains between the work travel position information WP and the start position Ls2 of the next work travel. As such, a display line L3 indicating the unworked part is displayed between the display line L1 based on the work travel position information WP and the display line L2 based on the start position Ls2 of the next work travel. Note that the width of the unworked part is a width over which tilling work can be performed between already-worked parts on both sides, without gaps, when performing the tilling work.

As described above, the guidance information for a right turn, indicated by <NUM>-B in <FIG> and <FIG>, is displayed in the display unit <NUM> on the basis of the process of step #<NUM>-<NUM> indicated in <FIG>, after the automatic travel control has been performed along the target travel route LM[n] and before the machine body <NUM> actually starts the turn. However, when, for example, the target travel route LM[n] is approaching a ridge, on one side of the field, that follows the target heading LA, it is conceivable that the machine body <NUM> cannot actually turn any further to the right from the work travel position information WP. If the machine body <NUM> has actually turned to the left as indicated in <FIG>, a left turn is determined in step #<NUM>-<NUM> of <FIG>, and the guidance information is changed to left turn guidance information, indicated by <NUM>-C in <FIG>, on the basis of the process of step #<NUM>-<NUM>. The start position Ls2 indicated in <FIG> is indicated as the planned start position Ls2' in <FIG>, and the planned start position Ls2' is not used as the start position Ls2 for generating the next target travel route LM.

In step #<NUM>-<NUM> indicated in <FIG>, the start position calculation unit 76D calculates the start position Ls2 for generating the next target travel route LM on the basis of the previous turning travel. Thus as a rule, the start position calculation unit 76D calculates the start position Ls2 for generating the next target travel route LM at a position separated from the work travel position information WP by the second separation distance P2. However, in <FIG>, the area of the work travel based on the target travel route LM[n-<NUM>] has already undergone work travel. Accordingly, if, when the machine body <NUM> makes a left turn, the start position Ls2 has been calculated at a position separated from the work travel position information WP by the second separation distance P2, the area that has already undergone work travel will overlap with the start position Ls2 of the next work travel. To avoid this problem, the start position calculation unit 76D searches for the start position Ls2 with priority given to unworked parts in areas on the left turn side. In the embodiment illustrated in <FIG>, an unworked part remains between the area of the work travel based on the target travel route LM[n-<NUM>] and the area of the work travel based on the target travel route LM[n], as described earlier on the basis of <FIG>. The width of this unworked part in the horizontal direction is equivalent to the work width of the tilling device <NUM>. As such, instead of the planned start position Ls2' indicated in <FIG>, the start position calculation unit 76D calculates the start position Ls2 for generating the next target travel route LM at a position separated from the work travel position information WP by the first separation distance P1. The target travel route LM[n+<NUM>] illustrated in <FIG> is a planned target travel route LM set after the machine body <NUM> has reached the start position Ls2.

After the above-described turning travel is complete, the manual maneuvering mode of the control device <NUM> is continued, and straight travel is continued on the basis of human operation. During this period, the control device <NUM> confirms the determination conditions for heading deviation of the machine body <NUM> relative to the target heading LA, the direction of the front wheels <NUM>, and the steering state of the steering wheel <NUM>, and determines whether or not the state is one in which the mode can switch to the automatic maneuvering mode. Then, if the state is one in which the control device <NUM> can switch to the automatic maneuvering mode, the automatic maneuvering control is started in response to the occupant operating the trigger switch <NUM>. Here, the occupant can, using the display unit <NUM>, visually confirm whether or not the state is one in which the control device <NUM> can switch to the automatic maneuvering mode. At the same time, guidance information that assists the occupant in making the maneuvering operations is displayed in the display unit <NUM>.

While the straight travel of the working machine based on human operations is continuing, a screen for the guidance information indicated by <NUM>-A to <NUM>-D in <FIG> is displayed in the display unit <NUM>. A map screen showing the machine body <NUM> and the surroundings of the machine body <NUM> is included in this guidance information. This guidance information is displayed in the side panel <NUM> illustrated in <FIG>, but may be displayed in the meter panel <NUM> displayed in the same drawing. A steering display <NUM> of the steering wheel <NUM>, and a heading deviation display <NUM> of the machine body <NUM> calculated by the heading deviation calculation unit <NUM> are displayed in a vertical arrangement at the right end of the guidance information screen. Additionally, a map screen including the machine body symbol SY is displayed in the screen to the left of the steering display <NUM> and the heading deviation display <NUM>, and in this map screen, already-worked parts, for which the tilling work is already complete, are indicated by a color indication WA. The color indication WA is calculated from the aggregation of the host vehicle positions NM stored in the storage unit <NUM> and the work width of the tilling device <NUM>. This makes a clear visual distinction between already-worked parts and unworked parts. The configuration may be such that of the areas in which the color indication WAis displayed, areas that have undergone work travel three or more times, areas that have undergone work travel twice, and areas that have only undergone work travel once are distinguished by different colors. In other words, the configuration may be such that the color indication WA is a different color depending on the number of times work travel has been performed, and the already-worked parts in the guidance information are displayed using color indications WA of different colors. The color indication WA may instead be point-based indications or pattern-based indications.

The determination to start the automatic maneuvering control is made on the basis of the flowchart illustrated in <FIG>. The control device <NUM> is configured to use a determination counter Ctr to determine whether or not the state is one in which the control device <NUM> can switch to the automatic maneuvering mode. The value of the counter Ctr immediately after the turning travel has ended is set to zero (step #<NUM>). First, it is determined whether or not the heading deviation of the machine body <NUM> is within a permissible range with respect to the target heading LA (step #<NUM>). If the heading of the machine body <NUM> is slanted to the right relative to the target heading LA (step #<NUM>: right slant), guidance information for a left turn, indicated by <NUM>-A in <FIG>, is displayed in the display unit <NUM> (step #<NUM>-<NUM>). The value of the counter Ctr is then reset to zero (step #<NUM>-<NUM>). Information prompting the occupant to turn the steering wheel <NUM> to the left is displayed in the guidance information for a left turn indicated by <NUM>-A in <FIG>. If the heading of the machine body <NUM> is slanted to the left relative to the target heading LA (step #<NUM>: left slant), guidance information for a right turn, indicated by <NUM>-B in <FIG>, is displayed in the display unit <NUM> (step #<NUM>-<NUM>). The value of the counter Ctr is then reset to zero (step #<NUM>-<NUM>). Information prompting the occupant to turn the steering wheel <NUM> to the right is displayed in the guidance information for a right turn indicated by <NUM>-B in <FIG>.

While the machine body <NUM> is traveling straight in a direction following the target heading LA (step #<NUM>: straight), the counter Ctr is incremented (step #<NUM>), and the value of the counter Ctr increases. It is then determined whether or not the machine body <NUM> has traveled at least a set distance (step #<NUM>). Here, the "set distance" may be a pre-set distance from the start position Ls2 (see <FIG>), or may be a pre-set distance from a state in which the machine body <NUM> travels straight in a direction following the target heading LA. If the machine body <NUM> has not traveled at least the set distance (step #<NUM>: No), the processing returns to step #<NUM>.

If the machine body <NUM> has traveled at least the set distance (step #<NUM>: Yes), it is determined whether a change in the turning angle of the steering wheel <NUM> remains within a permissible range (step #<NUM>). A state in which the steering wheel <NUM> is moved neither in the direction of a right turn nor in the direction of a left turn, and the directions of the front wheels <NUM> and the rear wheels <NUM> are parallel, can be given as an example of a turning angle of the steering wheel <NUM> for when automatic maneuvering control is permitted, but the state is not limited thereto. For example, if the travel area of the machine body <NUM> is a ground surface that slopes in the horizontal direction, there is a risk that if the machine body <NUM> simply continues traveling straight, the machine body <NUM> will gradually shift toward the lower ground in the left-right direction. In such a case, the direction of the front wheels <NUM> is kept steered toward the high ground in the left-right direction, and as a result, it is easier for the machine body <NUM> to advance along the target heading LA. Accordingly, the turning angle of the steering wheel <NUM> when the automatic maneuvering control is permitted also includes states in which the steering wheel <NUM> is steered in the directions of a right turn or a left turn, for example. In other words, the control device <NUM> is configured so that the automatic maneuvering control is permitted when the turning angle of the steering wheel <NUM> continues to be kept within a set range. If the change in the turning angle of the steering wheel <NUM> is not kept within the permissible range (step #<NUM>: No), the counter Ctr is reset to zero (step #<NUM>). Note that the configuration may be such that in the process of step #<NUM>, the value of the counter Ctr may be decremented to reduce the value of the counter Ctr rather than resetting the value of the counter Ctr to zero.

The guidance information indicated by <NUM>-C in <FIG> is displayed in the display unit <NUM> from when the straight travel is determined in step #<NUM> to when the determination of step #<NUM> is made. Then, when the counter Ctr has reached a pre-set value (step #<NUM>: Yes), the guidance information indicated by <NUM>-D in <FIG> is displayed in the display unit <NUM>, and the automatic maneuvering control is permitted. Then, the control mode of the control device <NUM> is switched from the manual maneuvering mode to the automatic maneuvering mode in response to the occupant operating the trigger switch <NUM>, and the automatic maneuvering control is executed (step #<NUM>). The configuration may be such that if a sharp turn of the steering wheel <NUM> is detected after a determination of Yes is made in step #<NUM> but before the occupant operates the trigger switch <NUM>, the value of the counter Ctr is reset to zero, decremented, or the like.

The present invention is not limited to the configuration described as an example in the foregoing embodiment, and examples of other representative embodiments of the present invention will be given hereinafter.

Claim 1:
A traveling work machine comprising:
a machine body (<NUM>) provided with a travel apparatus (<NUM>, <NUM>);
a position detection unit (<NUM>) configured to detect position information of the machine body (<NUM>) on the basis of a positioning signal of a navigation satellite;
a travel trajectory obtainment unit (<NUM>) configured to obtain a travel trajectory of the machine body (<NUM>) on the basis of detection, over time, of the position information;
a target heading calculation unit (76B) configured to calculate a target heading (LA) on the basis of the travel trajectory;
a maneuvering control unit (<NUM>) configured to control the travel apparatus (<NUM>, <NUM>) to maneuver along the target heading (LA);
a display unit (<NUM>) configured to display information pertaining to setting of the target heading (LA); and
a single operating tool (<NUM>, <NUM>) configured to set both a start point (Ts) and an end point (Tf) of the travel trajectory obtained when calculating the target heading (LA),
characterized in that:
the target heading calculation unit (76B) is configured to set the end point (Tf) through an operation of the operating tool (<NUM>, <NUM>) after the start point (Ts) has been set through an operation of the operating tool (<NUM>, <NUM>) and the machine body (<NUM>) has traveled a pre-set distance after the start point (Ts) has been set; and
when setting of the end point (Tf) through an operation of the operating tool (<NUM>, <NUM>) has become possible, the display unit (<NUM>) is configured to display an indication that the setting of the end point (Tf) is possible.