US20060195238A1 - Method and system for preventing automatic re-engagement of automatic vehicle control - Google Patents
Method and system for preventing automatic re-engagement of automatic vehicle control Download PDFInfo
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- US20060195238A1 US20060195238A1 US11/332,573 US33257306A US2006195238A1 US 20060195238 A1 US20060195238 A1 US 20060195238A1 US 33257306 A US33257306 A US 33257306A US 2006195238 A1 US2006195238 A1 US 2006195238A1
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Classifications
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D1/00—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
- G05D1/02—Control of position or course in two dimensions
- G05D1/021—Control of position or course in two dimensions specially adapted to land vehicles
- G05D1/0276—Control of position or course in two dimensions specially adapted to land vehicles using signals provided by a source external to the vehicle
- G05D1/0278—Control of position or course in two dimensions specially adapted to land vehicles using signals provided by a source external to the vehicle using satellite positioning signals, e.g. GPS
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01B—SOIL WORKING IN AGRICULTURE OR FORESTRY; PARTS, DETAILS, OR ACCESSORIES OF AGRICULTURAL MACHINES OR IMPLEMENTS, IN GENERAL
- A01B69/00—Steering of agricultural machines or implements; Guiding agricultural machines or implements on a desired track
- A01B69/007—Steering or guiding of agricultural vehicles, e.g. steering of the tractor to keep the plough in the furrow
- A01B69/008—Steering or guiding of agricultural vehicles, e.g. steering of the tractor to keep the plough in the furrow automatic
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D1/00—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
- G05D1/0055—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots with safety arrangements
- G05D1/0061—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots with safety arrangements for transition from automatic pilot to manual pilot and vice versa
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D1/00—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
- G05D1/02—Control of position or course in two dimensions
- G05D1/021—Control of position or course in two dimensions specially adapted to land vehicles
- G05D1/0268—Control of position or course in two dimensions specially adapted to land vehicles using internal positioning means
- G05D1/0272—Control of position or course in two dimensions specially adapted to land vehicles using internal positioning means comprising means for registering the travel distance, e.g. revolutions of wheels
Definitions
- Embodiments of the present invention are directed to controlling a mobile machine. More specifically, embodiments of the present invention relate to a method and system for preventing automatic re-engagement of an automatic vehicle control system.
- Guidance systems are increasingly used for controlling agricultural and environmental management equipment and operations such as road side spraying, road salting, and snow plowing where following a previously defined route is desirable. This allows more precise control of the vehicles than is typically realized than if the vehicle is steered by a human. Many agricultural vehicles rely upon furrow followers which mechanically detect whether the vehicle is moving parallel to a previously plowed plant furrow. However, these guidance systems are most effective in flat terrain and when detecting furrows plowed in a straight line. Additionally, many of these systems require factory installation and are too expensive or inconvenient to facilitate after market installation.
- a component for controlling the steering mechanism of the vehicle is used to control the movement of the vehicle in a desired direction.
- the guidance system generates a steering command which is implemented by the component which controls the steering mechanism.
- the controlling component is directly coupled with and manipulates hydraulic pumps which comprise the power steering system of the vehicle.
- Other controlling components manipulate the steering wheel of the vehicle.
- Prior art guidance systems are problematic in that there typically is no provision made for logically disengaging the guidance system. Thus, if a vehicle operator attempts to manually steer the vehicle (e.g., to pass to the side of a rock) the guidance system will continue trying to steer the vehicle in the original direction. This can be unsafe for the operator, or others in the vicinity, and may result in damage to the vehicle, or injury to the operator.
- prior art guidance systems are problematic because there is typically no provision for preventing them from automatically re-engaging. Thus, even if the guidance system is logically disengaged, it may automatically re-engage if one or more parameters for engagement is met. Again, this can be unsafe for the operator, or others in the vicinity, and may result in damage to the vehicle, or injury to the operator.
- Embodiments of the present invention recite a method and system for implementing automatic vehicle control with parameter-driven disengagement.
- a course for a vehicle is determined along which the vehicle is to be automatically guided.
- An indication is received that a pre-defined parameter has been exceeded.
- the generation of steering commands is then suspended.
- the generation of steering commands is suspended until an engagement signal is received.
- FIGS. 1A and 1B show an exemplary system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIG. 2 shows an exemplary system architecture in accordance with embodiments of the present invention.
- FIGS. 3A and 3B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIGS. 4A and 4B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIGS. 5A and 5B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIG. 6 is a flowchart of a method for implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIGS. 7A, 7B , 7 C, 7 D, and 7 E are a flowchart of a method for implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIG. 8 shows a vehicle implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention.
- FIG. 9 is a block diagram of an exemplary vehicle guidance system used in accordance with embodiments of the present invention.
- FIG. 10 is a flowchart of a method for preventing automatic re-engagement of automatic vehicle control in accordance with embodiments of the present invention.
- FIG. 11 shows an exemplary work area and the establishing of a headlands area in accordance with embodiments of the present invention.
- FIG. 1A is a block diagram of an exemplary system 100 for controlling a mobile machine 105 in accordance with embodiments of the present invention.
- system 100 is a vehicle guidance system used to generate and implement steering commands to facilitate controlling a vehicle automatically.
- a position determining system 110 is coupled with a control component 120 and a steering component 130 via a communication network or coupling 115 .
- system 100 may comprise an optional keypad 140 and/or a terrain compensation module (TCM) component (e.g., TCM 150 ) which are also coupled with coupling 115 .
- TCM terrain compensation module
- coupling 115 is a serial communications bus.
- coupling 115 is compliant with, but not limited to, the controller area network (CAN) protocol.
- CAN is a serial bus system which was developed for automotive use in the early 1980s.
- the Society of Automotive Engineers (SAE) has developed a standard CAN protocol, SAE J1939, based upon CAN specification 2.0.
- SAE J1939 specification provides plug-and-play capabilities and allows components from various suppliers to be easily integrated in an open architecture.
- embodiments of the present invention may be communicatively coupled using other communication systems such as a wireless network.
- Position determining system 110 determines the geographic position of mobile machine 105 .
- the term “geographic position” means the determining in at least two dimensions (e.g., latitude and longitude), the location of mobile machine 105 .
- position determining system 110 is a satellite based position determining system and receives navigation data from satellites via antenna 107 of FIG. 1B .
- satellite based position determining systems include the global positioning system (GPS) navigation system, a differential GPS system, a real-time kinematics (RTK) system, a networked RTK system, etc.
- control component 120 receives position data from position determining system 110 and generates commands for controlling mobile machine 105 .
- mobile machine 105 is an agricultural vehicle such as a tractor, a harvester, etc.
- control component 120 in response to position data received from position determining system 110 , control component 120 generates a message (e.g., a steering command) to steering component 130 which then controls the steering mechanism of mobile machine 105 .
- control component 120 is operable for generating steering commands to an electrical steering component and a hydraulic steering component depending upon the configuration of system 100 .
- keypad 140 provides additional input/output capabilities to system 100 .
- keypad 140 may also comprise a device drive which allows reading a media storage device such as a compact disk (CD), a digital versatile disk (DVD), a memory stick, or the like. This allows, for example, integrating data from various software applications such as mapping software in order to facilitate controlling the movement of mobile machine 105 . For example, field boundaries can be easily input into system 100 to facilitate controlling the movement of mobile machine 105 .
- TCM 150 also known as an “inertial measurement unit” or “IMU,” provides the ability to compensate for terrain variations which can reduce the precision of position determining system 110 in determining the geographic position of mobile machine 105 .
- IMU inertial measurement unit
- the antenna 107 of the position determining system 110 can be displaced to one side or the other with respect to the center line of mobile machine 105 , thus causing errors in determining the geographic position of mobile machine 105 .
- gaps or overlaps can occur when plowing across contoured terrain is being performed.
- TCM 150 can detect the magnitude of displacement of antenna 107 with respect to the center line of mobile machine 105 due to roll and yaw, and send signals which allow control component 120 to generate steering commands which compensate for the errors in determining the geographic position and heading of mobile machine 105 .
- TCM 150 can also detect the magnitude of displacement of antenna 107 with respect to the center line of mobile machine 105 due to pitch, and send signals which allow control component 120 to generate steering commands which compensate for the errors in determining the geographic position of mobile machine 105 .
- TCM 150 may also comprise acceleration sensors that determine whether excessive acceleration of vehicle 105 is occurring. This may include excessive lateral acceleration of vehicle 105 due to an excessively sharp turn radius, and excessive vertical acceleration of vehicle 105 due to rough terrain, or running into/over an obstacle (e.g., a ditch, or log). It is noted that in embodiments of the present invention, the determination of excessive acceleration, including lateral acceleration, of vehicle 105 may be determined using successive position fixes provided by position determining system 110 . For example, position determining system 110 may determine the geographic location of mobile machine every 100 milliseconds. Thus, it is possible to derive the turn rate (e.g., degrees or radians per second) of vehicle 105 using successive position fixes along with the present velocity of vehicle 105 .
- the turn rate e.g., degrees or radians per second
- the lateral forces associated with the turn currently being performed by vehicle 105 can be determined. This is important because vehicle 105 may be carrying heavy loads, or towing implements which could affect the stability of the vehicle during sharp turns. However, in embodiments of the present invention, this information can be accessed by system 100 in order to determine the maximum safe lateral acceleration to prevent an accident.
- FIG. 1 may be implemented as separate components. However, in embodiments of the present invention, these components may be integrated as various combinations of discreet components, or as a single device.
- seat switch 160 which is coupled with coupling 115 .
- seat switch 160 can detect when an operator is seated at the controls of vehicle 105 .
- seat switch 160 may comprise a pressure sensitive switch, or a pressure sensitive pad which is placed on top of the seat.
- seat switch 160 When vehicle 105 is being operated and the operator leaves the seat, seat switch 160 generates a signal which may cause control component 120 to suspend generating steering commands until the operator is again seated.
- control component will stop generating steering commands, thus preventing the actuation of the steering mechanism of vehicle 105 , until the operator is again seated in vehicle 105 .
- the operator may be required to manually re-engage system 100 again after sifting in vehicle 105 .
- system 100 further comprises a time out sensor 170 .
- the operator of vehicle 105 may be required to manually actuate a switch, or other sensor, periodically in order to confirm that the operator is still conscious and/or alert. This is sometimes referred to as a “deadman's switch.”
- a signal is generated which will prevent the generation of steering commands until the user manually actuates time out sensor 170 again.
- the time interval between actuations may be user defined, or a pre-set parameter.
- each actuation of time out sensor 170 may re-set the interval counter. For example, each time the operator actuates time out sensor 170 he/she may have up to 2 minutes in which to actuate time out sensor 170 again without interrupting the generation of steering commands by control component 120 .
- system 100 may also comprise a brake switch sensor 180 which is coupled with coupling 115 .
- a brake switch sensor 180 if an operator actuates the brake pedal of vehicle 105 , a signal from brake switch sensor 180 will cause control component 120 to stop generating steering commands. Thus, if the operator is trying to stop vehicle 105 , system 100 will cease trying to control the steering mechanism of the vehicle.
- FIG. 2 shows an exemplary system architecture 200 in accordance with embodiments of the present invention.
- control component 120 comprises a vehicle guidance system 210 which is coupled with a steering controller 220 .
- vehicle guidance system 210 and steering controller 220 may be implemented as a single unit, or separately.
- Implementing steering controller 220 separately is advantageous in that it facilitates implementing the present invention as an after market kit which can be easily added to an existing vehicle navigation system. As a result, the costs for components and for installation of the control system of the present invention are reduced.
- embodiments of the present invention are well suited to be factory installed as original equipment for mobile machine 105 as well.
- vehicle guidance system 210 uses position data from position determining system 110 , user input such as a desired pattern or direction, as well as vector data such as desired direction and distance to determine course corrections which are used for guiding mobile machine 105 .
- Roll, pitch, and yaw data from TCM 150 may also be used to determine course corrections for mobile machine 105 .
- course means a direction between at least two geographic positions.
- course correction means a change in the direction traveled by mobile machine 105 such that mobile machine 105 is guided from a current direction of travel to a desired direction of travel and/or a current geographic position to a desired geographic position.
- vehicle guidance system 210 is a commercially available guidance system such as the AgGPS® guidance system manufactured by Trimble Navigation Ltd. of Sunnyvale Calif.
- Additional data used to determine course corrections may also comprise swath calculation which takes into account the width of various implements which may be coupled with mobile machine 105 . For example, if a harvester can clear a swath of 15 feet in each pass, vehicle guidance system 210 may generate steering commands which cause mobile machine 105 to move 15 feet to one side in the next pass. Vehicle guidance system 210 may also be programmed to follow straight or curved paths which is useful when operating in irregularly shaped or contoured fields or in fields disposed around a center pivot. This is also useful in situations in which the path being followed by mobile machine 105 is obscured. For example, an operator of a snowplow may not be able to see the road being cleared due to the accumulation of snow on the road.
- position determining component 110 may be integrated into vehicle guidance system 210 or may be a separate unit. Additionally, as stated above with reference to FIG. 1 , position determining component 110 , control component 120 and steering component 130 may be integrated into a single unit in embodiments of the present invention.
- the course correction calculated by vehicle guidance system 210 is sent from vehicle guidance system 210 to steering controller 220 .
- Steering controller 220 translates the course correction generated by guidance system 210 into a steering command for manipulating the steering mechanism of mobile machine 105 .
- Steering controller 220 generates a message conveying the steering command to steering component 130 .
- the communicative coupling between vehicle guidance system 210 , steering controller 220 and steering component 130 may be accomplished using coupling 115 (e.g., a serial bus, or CAN bus).
- steering component 130 may comprise an electric steering component 131 , or a hydraulic steering component 132 .
- steering controller 220 comprises a first output 221 for coupling steering controller 220 with electric steering component 131 , and a second output 222 for coupling steering controller 220 with hydraulic steering component 132 . Because coupling 115 may be compliant with the CAN protocol, plug and play functionality is facilitated in system 200 . Therefore, in embodiments of the present invention, steering controller can determine which steering component it is coupled with depending upon which output of steering controller 220 is used.
- Steering controller 220 then generates a message, based upon the steering component with which it is coupled, which causes the steering component to actuate the steering mechanism of mobile machine 105 . For example, if steering controller 220 determines that output 221 is being used, it generates a steering command which is formatted for controlling electric steering component 131 . If steering controller 220 determines that output 222 is being used, it generates a steering command which is formatted for controlling hydraulic steering component 132 .
- the message sent by steering controller 220 may comprise a control voltage, control current, or a data message.
- FIGS. 3A and 3B show side and axial views respectively of a system 300 for controlling a mobile machine in accordance with embodiments of the present invention.
- a steering component e.g., electric steering component 131 of FIG. 2
- actuator device comprises a drive wheel 311 which is in contact with steering wheel 330 of mobile machine 105 .
- electric motor 310 may be directly coupled with drive wheel 311 , or may be coupled via a low ratio gear (not shown).
- the electric motor coupled with drive wheel 311 is a non-geared motor and the performance parameters of the electric motor coupled are selected so that, for example, electric motor 310 may be installed in a variety of vehicle types and/or manufacturers. For example, a certain amount of torque is desired in order to be able to turn steering wheel 330 . It is also important to determine a desired ratio between the torque generated by the motor and the electrical current driving the motor. Because there is a power loss across the transistors comprising control component 120 that are proportional to the square (X 2 ) of the current passing through the circuit, it is desirable to utilize a lower amount of current. However, if too little current is used, the motor turns too slowly to provide a desired level of responsiveness to steering commands.
- the torque constant e.g., ounce/inches per amp
- back-EMF an electromagnetic field
- the performance parameters of the electric motor are selected to more specifically match the motor with a particular vehicle type, model, or manufacturer.
- Electric steering component 131 further comprises a motor control unit 313 is coupled with electric motor 310 and with a control component 120 of FIG. 2 via coupling 115 .
- electric motor 310 is coupled with the steering column 340 via a bracket 320 .
- electric motor 310 may be coupled with steering column 340 using another apparatus than bracket 320 .
- electric motor 310 may be coupled with a bracket which is attached via suction cups with the windshield or dashboard of mobile machine 105 .
- electric motor 310 may be coupled with a pole which is extended between the floor and roof of mobile machine 105 .
- motor control unit 313 may be implemented as a sub-component of control unit 120 and may only send a control voltage to electric motor 310 via an electrical coupling (not shown).
- motor control unit 313 may be implemented as a separate unit which is communicatively coupled with control unit 120 via coupling 115 and with electric motor 310 via an electrical coupling (not shown).
- drive wheel 311 is coupled with steering wheel 330 with sufficient friction such that rotation of drive 311 causes rotation of steering wheel 330 .
- a spring (not shown) maintains sufficient pressure for coupling drive wheel 311 with steering wheel 330 .
- the spring does not maintain sufficient pressure between drive wheel 311 and steering wheel 330 to pinch a user's fingers if, for example, the user is manually steering mobile machine 105 and the user's fingers pass between drive wheel 311 and steering wheel 330 .
- FIGS. 3A and 3B show drive wheel 311 contacting the outside portion of steering wheel 330
- drive wheel 311 contact the inside portion of steering wheel 330 .
- electric motor 310 is reversable, thus, depending upon the steering command sent from control component 120 , motor control unit 313 controls the current to electric motor 310 such that it rotates in a clockwise or counter-clockwise direction. As a result, steering wheel 330 is turned in a clockwise or counter-clockwise direction as well.
- the current running through electric motor 310 is calibrated so that drive wheel 311 is turning steering wheel 330 without generating excessive torque. This facilitates allowing a user to override electric steering component 131 .
- electric motor 310 may be a permanent magnet brush direct current (DC) motor, a brushless DC motor, a stepper motor, or an alternating current (AC) motor.
- motor control unit 313 can detect when a user is turning steering wheel 330 in a direction counter to the direction electric steering component 131 is turning.
- a shaft encoder (not shown) may be used to determine which direction shaft 312 is turning.
- the shaft encoder detects that the user is turning steering wheel 330 and generates a signal to motor control unit 313 .
- motor control unit 313 can disengage the power supplied to electric motor 310 .
- electric motor 310 is now freewheeling and can be more easily operated by the user.
- motor control unit 313 when steering wheel 330 is turned counter to the direction electric motor is turning, a circuit in motor control unit 313 detects that electric motor 310 is stalling and disengages the power supplied to electric motor 310 .
- a switch detects the rotation of steering wheel 330 and sends a signal to motor control unit 313 . Motor control unit 313 can then determine that the user is manually steering mobile machine 105 and disengage electric motor 310 . As a result, when a user turns steering wheel 330 , their fingers will not be pinched if they pass between drive wheel 311 and steering wheel 330 because electric motor 310 is freewheeling when the power is disengaged.
- Embodiments of the present invention are advantageous over conventional vehicle control systems in that they can be easily and quickly installed as an after market kit.
- conventional control systems typically control a vehicle using solenoids and hydraulic flow valves which are coupled with the power steering mechanism of the vehicle. These systems are more difficult to install and more expensive than the above described system due to the higher cost of the solenoids and hydraulic flow valves as well as the additional labor involved in installing the system.
- the embodiment of FIG. 3 can be easily bolted onto steering column 340 and coupled with steering controller 220 .
- electric motor 310 can be fitted to a variety of vehicles by simply exchanging bracket 320 for one configured for a particular vehicle model.
- embodiments of the present invention do not rely upon furrow feelers which typically must be raised from and lowered into a furrow when the end of the furrow is reached. As a result, less time is lost in raising or lowering the furrow feeler.
- FIGS. 4A and 4B show side and axial views respectively of a system 400 for controlling a mobile machine in accordance with embodiments of the present invention.
- the steering component e.g., electric steering component 131 of FIG. 2
- the steering component comprises an electric motor 410 which is coupled with drive wheel 411 via shaft 412 and a motor control unit 413 .
- Motor control unit 413 couples electric motor 410 with steering controller 220 of FIG. 2 .
- electric motor 410 is connected with steering column 440 via bracket 420 .
- drive wheel 411 is coupled with a sub wheel 431 which is coupled with steering wheel 330 via brackets 432 .
- electric motor 410 turns in a clockwise or counter-clockwise direction depending upon the steering command received by motor control unit 413 .
- drive wheel 411 causes sub wheel 431 to turn in clockwise or counter clockwise direction as well.
- Utilizing sub wheel 431 prevents a user's fingers from being pinched between steering wheel 430 and drive wheel 411 if the user chooses to manually steer the vehicle.
- sub wheel 431 can be easily and quickly coupled with steering wheel 430 by, for example, attaching brackets 432 to the spokes of steering wheel 430 .
- FIGS. 5A and 5B are side and axial views respectively of a system 500 for controlling a mobile machine in accordance with embodiments of the present invention.
- the steering component e.g., electric steering component 131 of FIG. 2
- the steering component comprises an electric motor 510 which is coupled with gear 511 via shaft 512 and with a motor control unit 513 .
- Motor control unit 413 couples electric motor 510 with steering controller 220 of FIG. 2 .
- electric motor 510 is coupled with steering column 540 .
- FIG. 5B is a section view of system 500 and shows steering shaft 550 disposed within steering column 540 .
- a gear 551 couples steering shaft 550 with gear 511 of electric steering component 131 .
- electric motor 510 turns in a clockwise or counter clockwise direction depending upon the steering command received by motor control unit 513 .
- gear 511 also turns in a clockwise or counter clockwise direction, thus causing steering shaft 550 to turn due to the force conveyed by gear 551 .
- the present embodiment recites coupling electric steering component 131 with steering shaft 550 using gears
- embodiments of the present invention are well suited for using other mechanical couplings such as a gear and chain, a belt and pulleys, etc.
- FIG. 6 is a flowchart of a method 600 for implementing automatic vehicle control in accordance with embodiments of the present invention.
- method 600 is implemented by, for example, control component 120 of system 100 to facilitate implementing automatic vehicle control in a safe manner. It is noted that while the following discussions will cite using method 600 in conjunction with agricultural vehicles, embodiments of the present invention may be used in other applications such as construction equipment and/or road servicing equipment such as snowplows or salt spreading trucks.
- a course is determined for a vehicle along which the vehicle is to be automatically guided.
- a user of system 100 can enter coordinates which define a course for vehicle 105 .
- the user utilizes keypad 140 to manually enter the coordinates which define the course for the vehicle.
- the coordinates for more than one vehicle course may be entered by a user.
- a user can program system 100 to follow a path (e.g., a road) comprising a series of curves which may be defined as a series of short straight segments.
- a series of vehicle courses may define a road which vehicle 105 is guided along using system 100 .
- other information such as the width of vehicle 105 or an implement coupled therewith (e.g., a plow attachment) may be entered into system 105 . This facilitates determining a vector for steering vehicle 105 to avoid overplanting or creating gaps in coverage.
- the coordinates may be stored in a memory device coupled with system 100 .
- the coordinates of a previously stored vehicle course may be stored in a non-volatile memory or data storage device.
- the coordinates of the vehicle course may be determined by another computer system and transferred to system 100 using, for example, a portable memory storage device such as a SmartCard memory device, a universal serial bus (USB) memory device, or the like.
- a wireless communication system may communicatively couple vehicle 105 with a communication network (e.g., the Internet) from which the vehicle course coordinates are accessed.
- a user can drive vehicle 105 and set system 100 to continue the current direction for a designated distance.
- vehicle 105 can be driven around the periphery of a field to define the outer edge of the work area. In so doing, position determining system 110 can determine the geographic position of vehicle 105 and thus determine the edges of the field or work area.
- step 620 of FIG. 6 an indication is received that a pre-defined parameter has been exceeded.
- a pre-defined parameter has been exceeded.
- Embodiments of the present invention utilize a variety of pre-defined parameters which are used to define operating parameters for system 100 . For example, in embodiments of the present invention, when a system fault error is received (e.g., loss or degradation of a GPS signal, or other sensor), the generation of steering commands is suspended until the fault is corrected.
- a system fault error e.g., loss or degradation of a GPS signal, or other sensor
- other pre-defined parameters for system 100 comprise, but are not limited to, a minimum vehicle speed, a maximum vehicle speed, an approach angle between vehicle 105 and the course vector, a cross-track error limit (e.g., the distance between vehicle 105 and the course vector), braking of vehicle 105 , a signal from seat switch 180 or time out sensor 170 , excessive tilt/roll of vehicle 105 , excessive roughness of terrain, excessive acceleration (including lateral acceleration) of vehicle 105 , and/or a manual override by a user (e.g., manually steering vehicle 105 ).
- a minimum vehicle speed e.g., a maximum vehicle speed
- an approach angle between vehicle 105 and the course vector e.g., the distance between vehicle 105 and the course vector
- a cross-track error limit e.g., the distance between vehicle 105 and the course vector
- braking of vehicle 105 e.g., the distance between vehicle 105 and the course vector
- a signal from seat switch 180 or time out sensor 170
- step 630 of FIG. 6 the generation of a steering command is suspended in response to receiving the indication of step 620 .
- steering commands for automatically guiding vehicle 105 are automatically suspended.
- generating steering commands may not be resumed until vehicle 105 is again operating within the pre-defined parameters and/or until a user of vehicle 105 makes an indication that automatic vehicle control is to be resumed, thereby initiating a new vehicle guidance session.
- Embodiments of the present invention facilitate safe operation of an automatic vehicle guidance system because the automatic vehicle guidance system is logically disengaged when pre-defined parameters are exceeded.
- mechanical sensors e.g., furrow feelers
- the only way to disengage the guidance system was to manually disengage the steering motor from the steering wheel of the vehicle or to manually disengage the furrow feelers from the furrow.
- Embodiments of the present invention logically determine whether the vehicle is operating within a set of pre-defined parameters which may indicate that automatic vehicle control is desired by the user. For example, if system 100 detects that the user is manually steering vehicle 100 , it is likely that the user does not want system 100 to be generating steering commands. If these commands were implemented by a drive motor coupled with the steering wheel (e.g., electric motor 310 of FIG. 3 ), if may interfere with the user's control of the vehicle and lead to an unsafe operating condition. Additionally, if the vehicle is operated below a minimum vehicle speed, it may indicate that the user is attempting to stop the vehicle and thus may not want the automatic vehicle guidance system to take over operating the vehicle.
- a drive motor coupled with the steering wheel e.g., electric motor 310 of FIG. 3
- the stop/slow down action performed while transitioning to reverse causes system to be logically disengaged from controlling vehicle 105 .
- the user can press an engage button to re-engage the current course vector if desired.
- the vehicle is operated above a maximum vehicle speed, it may indicate that the user has driven off of a field and therefore does not want the automatic vehicle guidance system to take over operating the vehicle. Additionally, if the vehicle has exceeded a distance parameter from a portion of the course vector, it may indicate, for example, that the user has driven vehicle 105 off of a field and no longer desired automatic vehicle control to be implemented. Furthermore, if the user has driven vehicle 105 off of a field, but is now driving parallel to the field (e.g., on a road parallel to the field), the maximum speed parameter disengages the system 100 to prevent system 100 from attempting to control the vehicle while the user is operating vehicle 105 on the road.
- the maximum speed parameter disengages the system 100 to prevent system 100 from attempting to control the vehicle while the user is operating vehicle 105 on the road.
- embodiments of the present invention facilitate a logical disengagement of vehicle guidance system 100 while still allowing it to be physically coupled with the steering mechanism of the vehicle being controlled. This is much more convenient for users who previously had to manually disengage the drive motor from the steering wheel of the vehicle. For many users, this was especially tedious when performing repetitive operations, such as plowing a field, where manually disengaging the drive wheel was repeatedly performed.
- FIGS. 7A, 7B , 7 C, 7 D, and 7 E are a flowchart of a method 700 for implementing automatic vehicle control in accordance with embodiments of the present invention. It is noted that in addition to the steps shown in FIGS. 7A-7E , a user can suspend or terminate the operation of system 100 at any time by, for example, pressing a designated button. In step 701 of FIG. 7A , power is supplied to system 100 by a user pressing the power button of system 100 .
- a new guidance session is initiated.
- the user indicates that a new guidance session is being initiated.
- a sensor integrity check may be automatically performed when power is initiated to ensure that the sensors are providing valid information.
- a GPS sensor e.g., position determining system 110
- can be operating properly e.g., no system fault
- integrity checks for sensors other than position determining system may be performed at this time.
- step 703 of FIG. 7A course parameters for the new guidance session are received.
- system 100 accesses coordinates which define a vehicle course for vehicle 105 .
- a start point and end point of a swath also known as the “A-B line,” are entered into system 100 .
- step 704 of FIG. 7A the control system is engaged. Once the user has entered the coordinates defining a vehicle course, the user manually indicates that system 100 is to be engaged. This prevents system 100 from automatically engaging as soon as the vehicle course coordinates are entered into system 100 and automatically guiding vehicle 105 .
- step 705 of FIG. 7A velocity data is received.
- data is received from a variety of monitoring devices to determine the operating parameters of vehicle 105 .
- step 705 data indicating the current operating speed or velocity of vehicle 105 is received by control component 120 .
- a logical operation is performed to determine if the current velocity of vehicle 105 is above a minimum velocity parameter.
- control component 120 compares the current velocity of vehicle 105 received in step 705 with a pre-defined minimum velocity parameter. If vehicle 105 is not exceeding the minimum velocity parameter (e.g., 5 miles per hour), method 700 continues at step 725 and the generation of steering commands is suspended. If vehicle 105 is traveling above the minimum velocity parameter, method 700 proceeds to step 707 . In one embodiment, the current velocity of vehicle 105 must be above the minimum velocity parameter for five consecutive readings taken every 200 milliseconds (200 ms).
- a logical operation is performed to determine if the current velocity of vehicle 105 is below a maximum velocity parameter.
- control component 120 compares the current velocity of vehicle 105 received in step 705 with a pre-defined maximum velocity parameter. If vehicle 105 is exceeding the maximum velocity parameter (e.g., 15 miles per hour), method 700 continues at step 725 and the generation of steering commands is suspended. If vehicle 105 is traveling below the maximum velocity parameter, method 700 proceeds to step 708 . In one embodiment, the current velocity of vehicle 105 must be below the maximum velocity parameter for five consecutive readings taken every 200 milliseconds (200 ms).
- the current position data of vehicle 105 is accessed.
- the current position data of vehicle 105 is obtained from position determining system 110 .
- a series of positions of vehicle 105 may be accessed to determine the direction in which vehicle 105 is traveling.
- step 709 of FIG. 7B the course parameters received in step 703 are accessed.
- a course vector is determined.
- the course parameters received in step 703 define a first point, a second point, and a direction and distance between these two points. This information may be used in embodiments of the present invention to determine a vector of the course which is to be followed by vehicle 105 .
- step 711 of FIG. 7B the angle from the current position of vehicle 105 to the course vector of step 710 is determined.
- the current direction being traveled by vehicle 105 as determined in step 708 above, are compared with the direction of the course vector determined in step 710 above.
- step 712 of FIG. 7B a logical operation is performed to determine whether the angle from the current position of vehicle 105 to the course vector of step 710 is within a pre-defined parameter.
- a pre-defined entry angle parameter e.g. 300 from the course vector direction
- method 700 proceeds to step 725 and the generation of steering commands is suspended. If the angle between these two directions does not exceed the pre-defined entry angle parameter, method 700 proceeds to step 713 .
- the angle from the current position of vehicle 105 to the course vector of step 710 must be within the pre-defined approach angle parameter for five consecutive readings taken every 200 milliseconds (200 ms).
- step 713 of FIG. 7C the distance from the current position of vehicle 105 to a point on the course vector is determined.
- system 100 utilizes data from position determining system 110 to determine the current location of vehicle 105 .
- a logical operation is performed to determine whether the distance from the current position of vehicle 105 to a point on the course vector is within a pre-defined parameter.
- the course vector is defined as a series of geographic positions.
- system 100 may be used to determine the distance of vehicle 105 to a point comprising the course vector.
- a user can enter additional information into system 100 such as the width of an implement coupled with vehicle 105 .
- this information can be used to determine if the distance between vehicle 105 and a point of the course vector, also known as the “cross-track error,” exceeds a pre-defined parameter.
- the pre-defined distance parameter may define the maximum distance between vehicle 105 and a point on the course vector as being no farther than 3 feet,” of the implement coupled with vehicle 105 .
- method 700 proceeds to step 725 and the generation of steering commands is suspended. While the present embodiment recites a cross-track error of no more than 3 feet, this can be a greater or lesser number in embodiments of the present invention.
- method 700 if the distance between vehicle 105 and a point of the course vector exceeds the pre-defined cross-track error parameter, method 700 proceeds to step 725 and the generation of steering commands is suspended. If the distance between vehicle 105 and a point of the course vector does not exceed the pre-defined cross-track error parameter, method 700 proceeds to step 715 . In one embodiment, the distance from the current position of vehicle 105 to a point on the course vector must be within the pre-defined cross-track error parameter for five consecutive readings taken every 200 milliseconds (200 ms).
- step 715 of FIG. 7C the current flow data from a current sensor is accessed.
- motor control unit 313 is operable for determining the amount of current flowing into electric motor 310 and/or determining whether a user is manually operating steering wheel 330 of vehicle 105 .
- only current flow data is accessed by motor control unit 313 and is sent via coupling 115 to control component 120 .
- a logical operation is performed to determine if a manual disengagement of system 100 disqualifies automatic re-engagement. For example, based upon the data accessed in step 715 , system 100 can determine if a user is attempting to manually operate vehicle 105 . If the disengagement of system 100 is interpreted as an attempt by the operator of vehicle 105 to avoid a possible safety risk, re-engagement of automatic vehicle control is prevented and method 700 proceeds to step 725 wherein the generation of steering commands is suspended. If it is determined that there was not a disqualifying disengagement, method 700 proceeds to step 717 .
- a logical operation is performed to determine whether a system fault error has been received.
- device polling may be performed to determine if a system error condition exists with a component of system 100 .
- each component may independently generate a message to control component 120 conveying that a system error has occurred. It is noted that reception of a system fault error message may be received at any time in method 700 and cause an immediate suspension of steering commands.
- method 700 if a system fault error conditions exists, method 700 proceeds to step 725 and the generation of steering commands is suspended. If no system fault error condition exists, method 700 proceeds to step 718 .
- a logical operation is performed to determine whether the seat switch is engaged.
- a seat switch e.g., 160
- method 700 proceeds to step 719 . If it is determined that no operator is seated in vehicle 105 , method 700 proceeds to step 725 .
- a logical operation is performed to determine whether the time out period is within limits.
- system 100 may also comprise an optional time out sensor 170 .
- an operator or vehicle 105 periodically actuates time out sensor 170 to confirm that the operator is still conscious and/or alert. If the operator does not actuate time out sensor 170 within a pre-determined time out parameter, method 700 proceeds to step 725 . If the operator has actuated time out sensor 170 within the pre-determined time out parameter, method 700 proceeds to step 720 .
- step 720 of FIG. 7D a logical operation is performed to determine whether vehicle 105 is within an defined work area. If vehicle 105 is within an defined work area, method 700 proceeds to step 721 . If vehicle 105 is outside of an defined work area, method 700 proceeds to step 725 .
- vehicle 105 has been driven once around the periphery of field 1101 . While driving around the periphery of field 1101 , system 100 determines the geographic position of vehicle at various points around the periphery. In embodiments of the present invention, system 100 may define a border (e.g., 1105 ) relative to the location of the antenna of system 100 . In the example of FIG.
- the border is defined at the inner edge of implement 801 . However, it is noted that the border may be defined at a greater or lesser distance relative to the location of antenna 107 in embodiments of the present invention.
- the area (e.g., 1150 ) between border 1105 and the outer edge of field 1101 is referred to as the “headlands.” Typically, no planting or spraying is performed in the headlands area.
- the area within border 1105 is defined as the work area (e.g., 1160 ) for vehicle 105 .
- vehicle 105 In operation, when the operator begins swath 1110 , vehicle 105 is driven to point 1111 . Because vehicle 105 is outside of the work area when driving within headlands 1150 , system 100 is automatically disengaged. Furthermore, while vehicle is outside of work area 1160 , system 100 will not automatically re-engage. In other words, unless a manually activated engagement signal is received, system 100 does not generate steering commands. After completing swath 1110 , vehicle 105 is outside of work area 1160 and system 100 is automatically disengaged. As a result, vehicle 105 has to be manually turned through turn 1115 . Upon reaching point 1121 of swath 1120 , the operator can manually re-engage system 100 .
- the operator also enters data which defines point 1122 of swath 1120 and system 100 determines a vector which comprises points 1121 and 1122 .
- the swath calculation is performed by system 100 .
- system 100 will guide vehicle 105 on a course that is essentially parallel with swath 1110 and displaced by a distance which approximates the width of implement 801 . It is noted that when vehicle 105 is driven to a different field or work area, system 100 disengages to permit the operator to manually steer the vehicle.
- the method for establishing a work area discussed above is one of a variety of methods for doing so.
- the work area may be defined by accessing previously stored data via, for example, a media storage device, or via a wireless data connection.
- step 721 a logical operation is performed to determine whether the brake of vehicle 105 has been activated.
- embodiments of the present invention may optionally comprise a brake switch sensor (e.g., 180 ) which indicates whether an operator of vehicle 105 has activated the braking system. If it is determined that the operator has actuated the braking system, method 700 proceeds to step 725 . If it is determined that the operator has not yet actuated the braking system, method 700 proceeds to step 722 .
- a logical operation is performed to determine whether the motion of vehicle 105 is within roll, pitch, or yaw limits, or a combination thereof. This can be determined by accessing data from TCM 150 which may utilize motion sensors to determine whether excessive motion of vehicle 105 is exhibited in one or more of these planes of motion. Alternatively, this information can be determined by accessing position data from position determining system 110 . If it is determined that excessive motion in one or more of these planes of motion is within pre-determined limits, method 700 proceeds to step 723 . If it is determined that excessive motion in one or more of these planes of motion is not within pre-determined limits, method 700 proceeds to step 725 .
- a logical operation is performed to determine whether acceleration of vehicle 105 is within pre-determined limits.
- TCM 150 can be used to determine whether vehicle 105 has been accelerated beyond pre-determined limits. This may indicate whether vehicle 105 has struck an object, or run into a ditch, rolled over, etc.
- method 700 proceeds to step 724 . If it is determined that acceleration of vehicle 105 exceeds the pre-determined limits, method 700 proceeds to step 725 .
- step 724 of FIG. 7E a logical operation is performed to determine whether valid GPS information is being received. This step is similar to the sensor integrity check performed as described above with reference to step 702 . It is noted that the sensor integrity check may be performed on a position determining system other than GPS in embodiments of the present invention. If the GPS system (e.g., position determining system 110 of FIG. 1 ) is receiving valid information, method 700 returns to step 705 . If it is determined that the GPS system is not receiving valid information, method 700 proceeds to step 725 .
- the GPS system e.g., position determining system 110 of FIG. 1
- step 725 of FIG. 7C the generation of a steering command is suspended.
- steering commands from steering controller are suspended.
- the steering commands are simply not conveyed to steering component 130 .
- the steering commands are not generated at all.
- course commands from vehicle guidance system 210 may be interrupted to prevent steering controller 220 from generating the steering commands.
- FIG. 8 shows a vehicle implementing automatic vehicle control in accordance with embodiments of the present invention.
- a user is operating a tractor (e.g., vehicle 105 ) pulling a plow 801 in a field 810 .
- the user initiates vehicle guidance system 100 and indicates that a new guidance session is being initiated.
- the user then enters the coordinates (e.g., first coordinate 821 and second coordinate 822 ) of first swath 820 .
- system 100 determines the geographic position of first coordinate 821 and second coordinate 822 , and a direction and distance of the vector between these two points. In so doing, system 100 has determined a course (e.g., first swath 820 ) for vehicle 105 .
- Vehicle operation commences when the user engages system 100 by pressing an engage button.
- Vehicle 105 then proceeds down swath 820 based upon steering commands generated by control component 120 .
- the user controls the speed of vehicle 105 while guidance system 100 automatically controls the steering of vehicle 105 to guide it along the course defined by first swath 820 .
- steering commands continue to be generated by system 100 .
- Vehicle guidance system 100 detects that the user is manually controlling vehicle 105 (e.g., step 716 of FIG. 7 ) and automatically suspends generating steering commands. This prevents system 100 from generating steering commands in an attempt to direct vehicle 105 back onto first swath 820 and thus conflicting with the manual operation of vehicle 105 .
- vehicle guidance system 210 continues to generate vehicle course commands to steering controller 220 , however, steering controller 220 does not generate steering commands in response to those course commands.
- vehicle course commands from vehicle guidance system 210 are suspended as well.
- first coordinate 841 can be determined by system 100 to position the edge of plow 801 so that gaps or overplowing is minimized.
- system 100 will again initiate automatically controlling the steering of vehicle 105 as it is guided along the course of swath 840 . Additionally, system 100 can indicate to the user that control of the steering can be relinquished by the user at some point on turn 830 . System 100 will then control the steering of vehicle 105 so that it is guided to first point 841 automatically and continue to steer the vehicle along that course.
- swath 840 the user again manually steers vehicle 105 through the turn defined by arrow 850 .
- the user can enter the coordinates of swath 860 (e.g., first coordinate 861 and second coordinate 862 ), press the engage button, and system 100 will generate steering commands to guide vehicle 105 along swath 860 .
- system 100 determines that vehicle 105 has exceeded the distance parameter. For example, the distance between vehicle 105 and swath 860 now exceeds the maximum cross-track error distance of 3 swaths based upon the width of plow 801 .
- portions of the present invention are comprised of computer-readable and computer-executable instructions that reside, for example, in vehicle guidance system 210 . It is appreciated that vehicle guidance system 210 of FIG. 9 is exemplary only and that the present invention can be implemented by other computer systems as well.
- vehicle guidance system 210 includes an address/data bus 901 for conveying digital information between the various components, a central processor unit (CPU) 902 for processing the digital information and instructions, a volatile main memory 903 comprised of volatile random access memory (RAM) for storing the digital information and instructions, and a non-volatile read only memory (ROM) 904 for storing information and instructions of a more permanent nature.
- vehicle guidance system 210 may also include a data storage device 905 (e.g., a magnetic, optical, floppy, or tape drive or the like) for storing vast amounts of data.
- Vehicle guidance system 210 further comprises a first communication interface 906 coupled with bus 901 for receiving geographic position data from position determining system 110 .
- Vehicle guidance system 210 also comprises a second communication interface 907 coupled with bus 901 for conveying course correction commands to steering controller 220 .
- first communication interface 906 and second communication interface 907 are serial communication interfaces.
- FIG. 10 is a flowchart of a method 1000 for preventing automatic re-engagement of automatic vehicle control in accordance with embodiments of the present invention. It is noted that method 1000 may be implemented by system 100 described above with reference to FIG. 1A .
- step 1010 a course for guiding a vehicle between a first geographic position and a second geographic position using an automatic vehicle control system is determined.
- system 100 can receive manually input coordinates from a user, a media storage device (e.g., a memory device), via a wireless data communication link, derived from current course data, or a combination thereof.
- a media storage device e.g., a memory device
- step 1020 of FIG. 10 an indication is received that a pre-defined parameter of the automatic vehicle control system has been exceeded.
- parameters which are monitored by system 100 which indicate when it may be advantageous to logically disengage system 100 .
- system 100 may attempt to guide vehicle 105 toward an obstacle or object which the operator of vehicle 105 is actively trying to avoid.
- system 100 may attempt to steer vehicle 105 back to the field that vehicle 105 has just left. Again, this may cause an unsafe situation for the operator and others in the vicinity.
- step 1030 of FIG. 10 the generation of steering commands via the automatic vehicle control system is suspended in response to receiving the indication as described above with reference to step 1020 .
- step 630 of FIG. 6 if one of the pre-defined parameters is exceeded, the generation of steering commands for vehicle 105 is suspended. This prevents system 100 from controlling the direction of vehicle 105 . As stated above, this can be dangerous when the operator of vehicle 105 is attempting to manually control the vehicle. As another example, if vehicle 105 has run into a ditch, or is about to, continued control of the vehicle by system 100 may further exacerbate an already dangerous situation.
- step 1040 of FIG. 10 the automatic re-engagement of the automatic vehicle control system is prevented until an engagement signal is received.
- an engagement signal is received by control component 120
- the generation of steering commands continues to be suspended.
- course corrections may continue to be calculated by vehicle guidance system 210 . However, they may not be sent to steering controller 220 in order to generate a steering command.
- the engagement signal is manually input by the operator of vehicle 105 .
- embodiments of the present invention prevent unintentional engagement of the automatic vehicle control system. As described above, this is advantageous in situations in which the operator has initiated manual control of the vehicle such as to avoid an obstacle or to drive between separate work areas.
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Abstract
Embodiments of the present invention recite a method and system for implementing automatic vehicle control with parameter-driven disengagement. In one embodiment, a course for a vehicle is determined along which the vehicle is to be automatically guided. An indication is received that a pre-defined parameter has been exceeded. In response to receiving the indication, the generation of steering commands is then suspended. Furthermore, the generation of steering commands is suspended until an engagement signal is received.
Description
- The present invention benefits from U.S. patent application Ser. No. 11/000,738 filed Nov. 30, 2004 titled “A Method and System for Implementing Automatic Vehicle Control with Parameter-Driven Disengagement,” by Mark Gibson, Charles Manning, and Arthur Lange, assigned to the assignee of the present invention, and which is hereby incorporated by reference in its entirety herein.
- Embodiments of the present invention are directed to controlling a mobile machine. More specifically, embodiments of the present invention relate to a method and system for preventing automatic re-engagement of an automatic vehicle control system.
- Operating agricultural vehicles such as tractors and harvesters often requires highly repetitive operations. For example, when plowing or planting a field, an operator must make repeated passes across a field. Due to the repetitive nature of the work and irregularities in the terrain, gaps and overlaps in the rows of crops can occur. This can result in damaged crops, overplanting, or reduced yield per acre. As the size of agricultural vehicles and farming implements continues to increase, precisely controlling their motion becomes more important.
- Guidance systems are increasingly used for controlling agricultural and environmental management equipment and operations such as road side spraying, road salting, and snow plowing where following a previously defined route is desirable. This allows more precise control of the vehicles than is typically realized than if the vehicle is steered by a human. Many agricultural vehicles rely upon furrow followers which mechanically detect whether the vehicle is moving parallel to a previously plowed plant furrow. However, these guidance systems are most effective in flat terrain and when detecting furrows plowed in a straight line. Additionally, many of these systems require factory installation and are too expensive or inconvenient to facilitate after market installation.
- A component for controlling the steering mechanism of the vehicle is used to control the movement of the vehicle in a desired direction. Thus, the guidance system generates a steering command which is implemented by the component which controls the steering mechanism. Often, the controlling component is directly coupled with and manipulates hydraulic pumps which comprise the power steering system of the vehicle. Other controlling components manipulate the steering wheel of the vehicle.
- Prior art guidance systems are problematic in that there typically is no provision made for logically disengaging the guidance system. Thus, if a vehicle operator attempts to manually steer the vehicle (e.g., to pass to the side of a rock) the guidance system will continue trying to steer the vehicle in the original direction. This can be unsafe for the operator, or others in the vicinity, and may result in damage to the vehicle, or injury to the operator.
- Additionally, prior art guidance systems are problematic because there is typically no provision for preventing them from automatically re-engaging. Thus, even if the guidance system is logically disengaged, it may automatically re-engage if one or more parameters for engagement is met. Again, this can be unsafe for the operator, or others in the vicinity, and may result in damage to the vehicle, or injury to the operator.
- Accordingly, a need exists for a method and system for implementing automatic vehicle control which facilitates logically disengaging the guidance system from a steering control apparatus without requiring that the steering control apparatus be physically disengaged from the steering mechanism of the vehicle.
- Embodiments of the present invention recite a method and system for implementing automatic vehicle control with parameter-driven disengagement. In one embodiment, a course for a vehicle is determined along which the vehicle is to be automatically guided. An indication is received that a pre-defined parameter has been exceeded. In response to receiving the indication, the generation of steering commands is then suspended. Furthermore, the generation of steering commands is suspended until an engagement signal is received.
- The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments of the present invention and, together with the description, serve to explain the principles of the invention. Unless specifically noted, the drawings referred to in this description should be understood as not being drawn to scale.
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FIGS. 1A and 1B show an exemplary system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIG. 2 shows an exemplary system architecture in accordance with embodiments of the present invention. -
FIGS. 3A and 3B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIGS. 4A and 4B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIGS. 5A and 5B show side and axial views respectively of a system for controlling a mobile machine with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIG. 6 is a flowchart of a method for implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIGS. 7A, 7B , 7C, 7D, and 7E are a flowchart of a method for implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIG. 8 shows a vehicle implementing automatic vehicle control with parameter-driven disengagement in accordance with embodiments of the present invention. -
FIG. 9 is a block diagram of an exemplary vehicle guidance system used in accordance with embodiments of the present invention. -
FIG. 10 is a flowchart of a method for preventing automatic re-engagement of automatic vehicle control in accordance with embodiments of the present invention. -
FIG. 11 shows an exemplary work area and the establishing of a headlands area in accordance with embodiments of the present invention. - Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. While the present invention will be described in conjunction with the following embodiments, it will be understood that they are not intended to limit the present invention to these embodiments alone. On the contrary, the present invention is intended to cover alternatives, modifications, and equivalents which may be included within the spirit and scope of the present invention as defined by the appended claims. Furthermore, in the following detailed description of the present invention, numerous specific details are set forth-in order to provide a thorough understanding of the present invention. However, embodiments of the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the present invention.
- Notation and Nomenclature
- Some portions of the detailed descriptions which follow are presented in terms of procedures, logic blocks, processing and other symbolic representations of operations on data bits within a computer memory. These descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. In the present application, a procedure, logic block, process, or the like, is conceived to be a self-consistent sequence of steps or instructions leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, although not necessarily, these quantities take the form of electrical or magnetic signal capable of being stored, transferred, combined, compared, and otherwise manipulated in a computer system.
- It should be borne in mind, however, that all of these and similar terms are to be associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise as apparent from the following discussions, it is appreciated that throughout the present invention, discussions utilizing terms such as “determining,” “receiving,” “suspending,” “using,” or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms data represented as physical (electronic) quantities within the computer system's registers and memories into other data similarly represented as physical quantities within the computer system memories or registers or other such information storage, transmission or display devices.
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FIG. 1A is a block diagram of anexemplary system 100 for controlling amobile machine 105 in accordance with embodiments of the present invention. In embodiments of the present invention,system 100 is a vehicle guidance system used to generate and implement steering commands to facilitate controlling a vehicle automatically. InFIG. 1A , aposition determining system 110 is coupled with acontrol component 120 and asteering component 130 via a communication network orcoupling 115. Additionally,system 100 may comprise anoptional keypad 140 and/or a terrain compensation module (TCM) component (e.g., TCM 150) which are also coupled withcoupling 115. - In embodiments of the present invention,
coupling 115 is a serial communications bus. In one embodiment,coupling 115 is compliant with, but not limited to, the controller area network (CAN) protocol. CAN is a serial bus system which was developed for automotive use in the early 1980s. The Society of Automotive Engineers (SAE) has developed a standard CAN protocol, SAE J1939, based upon CAN specification 2.0. The SAE J1939 specification provides plug-and-play capabilities and allows components from various suppliers to be easily integrated in an open architecture. However, embodiments of the present invention may be communicatively coupled using other communication systems such as a wireless network. -
Position determining system 110 determines the geographic position ofmobile machine 105. For the purposes of the present invention, the term “geographic position” means the determining in at least two dimensions (e.g., latitude and longitude), the location ofmobile machine 105. In one embodiment of the present invention,position determining system 110 is a satellite based position determining system and receives navigation data from satellites viaantenna 107 ofFIG. 1B . Examples of satellite based position determining systems include the global positioning system (GPS) navigation system, a differential GPS system, a real-time kinematics (RTK) system, a networked RTK system, etc. While the present embodiment recites these position determining systems specifically, it is appreciated that embodiments of the present invention are well suited for using other position determining systems as well such as ground-based position determining systems, or other satellite-based position determining systems such as the GLONASS system, or the Galileo system currently under development. - In embodiments of the present invention,
control component 120 receives position data fromposition determining system 110 and generates commands for controllingmobile machine 105. In embodiments of the present invention,mobile machine 105 is an agricultural vehicle such as a tractor, a harvester, etc. However, embodiments of the present invention are well suited for controlling other vehicles such as snow plows, construction equipment, road salting, or roadside spraying equipment as well. In one embodiment, in response to position data received fromposition determining system 110,control component 120 generates a message (e.g., a steering command) tosteering component 130 which then controls the steering mechanism ofmobile machine 105. In embodiments of the present invention,control component 120 is operable for generating steering commands to an electrical steering component and a hydraulic steering component depending upon the configuration ofsystem 100. - In embodiments of the present invention,
keypad 140 provides additional input/output capabilities tosystem 100. In embodiments of the present invention,keypad 140 may also comprise a device drive which allows reading a media storage device such as a compact disk (CD), a digital versatile disk (DVD), a memory stick, or the like. This allows, for example, integrating data from various software applications such as mapping software in order to facilitate controlling the movement ofmobile machine 105. For example, field boundaries can be easily input intosystem 100 to facilitate controlling the movement ofmobile machine 105. -
TCM 150, also known as an “inertial measurement unit” or “IMU,” provides the ability to compensate for terrain variations which can reduce the precision ofposition determining system 110 in determining the geographic position ofmobile machine 105. For example, when traversing a hillside, theantenna 107 of theposition determining system 110 can be displaced to one side or the other with respect to the center line ofmobile machine 105, thus causing errors in determining the geographic position ofmobile machine 105. As a result, gaps or overlaps can occur when plowing across contoured terrain is being performed. In one embodiment,TCM 150 can detect the magnitude of displacement ofantenna 107 with respect to the center line ofmobile machine 105 due to roll and yaw, and send signals which allowcontrol component 120 to generate steering commands which compensate for the errors in determining the geographic position and heading ofmobile machine 105. - In another embodiment,
TCM 150 can also detect the magnitude of displacement ofantenna 107 with respect to the center line ofmobile machine 105 due to pitch, and send signals which allowcontrol component 120 to generate steering commands which compensate for the errors in determining the geographic position ofmobile machine 105. - In embodiments of the present invention,
TCM 150 may also comprise acceleration sensors that determine whether excessive acceleration ofvehicle 105 is occurring. This may include excessive lateral acceleration ofvehicle 105 due to an excessively sharp turn radius, and excessive vertical acceleration ofvehicle 105 due to rough terrain, or running into/over an obstacle (e.g., a ditch, or log). It is noted that in embodiments of the present invention, the determination of excessive acceleration, including lateral acceleration, ofvehicle 105 may be determined using successive position fixes provided byposition determining system 110. For example,position determining system 110 may determine the geographic location of mobile machine every 100 milliseconds. Thus, it is possible to derive the turn rate (e.g., degrees or radians per second) ofvehicle 105 using successive position fixes along with the present velocity ofvehicle 105. As a result, the lateral forces associated with the turn currently being performed byvehicle 105 can be determined. This is important becausevehicle 105 may be carrying heavy loads, or towing implements which could affect the stability of the vehicle during sharp turns. However, in embodiments of the present invention, this information can be accessed bysystem 100 in order to determine the maximum safe lateral acceleration to prevent an accident. - It is appreciated that the components described with reference to
FIG. 1 may be implemented as separate components. However, in embodiments of the present invention, these components may be integrated as various combinations of discreet components, or as a single device. - Also shown in
FIG. 1A is aseat switch 160 which is coupled withcoupling 115. In embodiments of the present invention,seat switch 160 can detect when an operator is seated at the controls ofvehicle 105. In embodiments of the present invention,seat switch 160 may comprise a pressure sensitive switch, or a pressure sensitive pad which is placed on top of the seat. Whenvehicle 105 is being operated and the operator leaves the seat,seat switch 160 generates a signal which may causecontrol component 120 to suspend generating steering commands until the operator is again seated. Thus, if the operator leaves vehicle 105 (e.g., to remove an obstacle), control component will stop generating steering commands, thus preventing the actuation of the steering mechanism ofvehicle 105, until the operator is again seated invehicle 105. In embodiments of the present invention, the operator may be required to manually re-engagesystem 100 again after sifting invehicle 105. - In
FIG. 1A ,system 100 further comprises a time outsensor 170. In embodiments of the present invention, the operator ofvehicle 105 may be required to manually actuate a switch, or other sensor, periodically in order to confirm that the operator is still conscious and/or alert. This is sometimes referred to as a “deadman's switch.” In embodiments of the present invention, if an operator fails to actuate time outsensor 170 within a given time period, a signal is generated which will prevent the generation of steering commands until the user manually actuates time outsensor 170 again. In embodiments of the present invention, the time interval between actuations may be user defined, or a pre-set parameter. Additionally, each actuation of time outsensor 170 may re-set the interval counter. For example, each time the operator actuates time outsensor 170 he/she may have up to 2 minutes in which to actuate time outsensor 170 again without interrupting the generation of steering commands bycontrol component 120. - Continuing with
FIG. 1A ,system 100 may also comprise abrake switch sensor 180 which is coupled withcoupling 115. In embodiments of the present invention, if an operator actuates the brake pedal ofvehicle 105, a signal frombrake switch sensor 180 will causecontrol component 120 to stop generating steering commands. Thus, if the operator is trying to stopvehicle 105,system 100 will cease trying to control the steering mechanism of the vehicle. -
FIG. 2 shows anexemplary system architecture 200 in accordance with embodiments of the present invention. In the embodiment ofFIG. 2 ,control component 120 comprises avehicle guidance system 210 which is coupled with asteering controller 220. It is appreciated that in embodiments of the present invention,vehicle guidance system 210 andsteering controller 220 may be implemented as a single unit, or separately. Implementingsteering controller 220 separately is advantageous in that it facilitates implementing the present invention as an after market kit which can be easily added to an existing vehicle navigation system. As a result, the costs for components and for installation of the control system of the present invention are reduced. However, embodiments of the present invention are well suited to be factory installed as original equipment formobile machine 105 as well. - In embodiments of the present invention,
vehicle guidance system 210 uses position data fromposition determining system 110, user input such as a desired pattern or direction, as well as vector data such as desired direction and distance to determine course corrections which are used for guidingmobile machine 105. Roll, pitch, and yaw data fromTCM 150 may also be used to determine course corrections formobile machine 105. For purposes of the present invention, the term “course” means a direction between at least two geographic positions. For purposes of the present invention, the term “course correction” means a change in the direction traveled bymobile machine 105 such thatmobile machine 105 is guided from a current direction of travel to a desired direction of travel and/or a current geographic position to a desired geographic position. In embodiments of the present invention,vehicle guidance system 210 is a commercially available guidance system such as the AgGPS® guidance system manufactured by Trimble Navigation Ltd. of Sunnyvale Calif. - Additional data used to determine course corrections may also comprise swath calculation which takes into account the width of various implements which may be coupled with
mobile machine 105. For example, if a harvester can clear a swath of 15 feet in each pass,vehicle guidance system 210 may generate steering commands which causemobile machine 105 to move 15 feet to one side in the next pass.Vehicle guidance system 210 may also be programmed to follow straight or curved paths which is useful when operating in irregularly shaped or contoured fields or in fields disposed around a center pivot. This is also useful in situations in which the path being followed bymobile machine 105 is obscured. For example, an operator of a snowplow may not be able to see the road being cleared due to the accumulation of snow on the road. Additionally, visibility may be obscured by snow, rain, or fog. Thus, it would be advantageous to utilize embodiments of the present invention to guidemobile machine 105 in these conditions. In embodiments of the present invention,position determining component 110 may be integrated intovehicle guidance system 210 or may be a separate unit. Additionally, as stated above with reference toFIG. 1 ,position determining component 110,control component 120 andsteering component 130 may be integrated into a single unit in embodiments of the present invention. - In embodiments of the present invention, the course correction calculated by
vehicle guidance system 210 is sent fromvehicle guidance system 210 to steeringcontroller 220. -
Steering controller 220 translates the course correction generated byguidance system 210 into a steering command for manipulating the steering mechanism ofmobile machine 105.Steering controller 220 generates a message conveying the steering command tosteering component 130. In embodiments of the present invention, the communicative coupling betweenvehicle guidance system 210, steeringcontroller 220 andsteering component 130 may be accomplished using coupling 115 (e.g., a serial bus, or CAN bus). - In embodiments of the present invention,
steering component 130 may comprise anelectric steering component 131, or ahydraulic steering component 132. Thus, as shown inFIG. 2 , steeringcontroller 220 comprises afirst output 221 forcoupling steering controller 220 withelectric steering component 131, and asecond output 222 forcoupling steering controller 220 withhydraulic steering component 132. Becausecoupling 115 may be compliant with the CAN protocol, plug and play functionality is facilitated insystem 200. Therefore, in embodiments of the present invention, steering controller can determine which steering component it is coupled with depending upon which output ofsteering controller 220 is used. -
Steering controller 220 then generates a message, based upon the steering component with which it is coupled, which causes the steering component to actuate the steering mechanism ofmobile machine 105. For example, if steeringcontroller 220 determines thatoutput 221 is being used, it generates a steering command which is formatted for controllingelectric steering component 131. If steeringcontroller 220 determines thatoutput 222 is being used, it generates a steering command which is formatted for controllinghydraulic steering component 132. In embodiments of the present invention, the message sent by steeringcontroller 220 may comprise a control voltage, control current, or a data message. -
FIGS. 3A and 3B show side and axial views respectively of asystem 300 for controlling a mobile machine in accordance with embodiments of the present invention. In the embodiment ofFIG. 3A , a steering component (e.g.,electric steering component 131 ofFIG. 2 ) comprises anelectric motor 310 which is coupled with an actuator device via ashaft 312. In the embodiment ofFIG. 3A , actuator device comprises adrive wheel 311 which is in contact withsteering wheel 330 ofmobile machine 105. In embodiments of the present invention,electric motor 310 may be directly coupled withdrive wheel 311, or may be coupled via a low ratio gear (not shown). Using these methods to coupleelectric motor 313 and drivewheel 311 are advantageous in that a smaller electric motor can be used while still generating sufficient torque to controlsteering wheel 330. Thus, if a user wants to manually steermobile machine 105, the user will encounter less resistance fromelectric motor 310 when the motor is disengaged. - In embodiments of the present invention, the electric motor coupled with
drive wheel 311 is a non-geared motor and the performance parameters of the electric motor coupled are selected so that, for example,electric motor 310 may be installed in a variety of vehicle types and/or manufacturers. For example, a certain amount of torque is desired in order to be able to turnsteering wheel 330. It is also important to determine a desired ratio between the torque generated by the motor and the electrical current driving the motor. Because there is a power loss across the transistors comprisingcontrol component 120 that are proportional to the square (X2) of the current passing through the circuit, it is desirable to utilize a lower amount of current. However, if too little current is used, the motor turns too slowly to provide a desired level of responsiveness to steering commands. Additionally, if the torque constant (e.g., ounce/inches per amp) is too high, excessive “back-EMF,” which is an electromagnetic field, is generated by the motor and interferes with the current flowing into the motor. While a higher voltage can overcome the back-EMF issue, most vehicles utilize 12 volt batteries, thus indicating that a higher amount of current is desired. In embodiments of the present invention, a non-geared electric motor which generates approximately nineteen ounce/inches of torque per amp of current is utilized. In other embodiments of the present invention, the performance parameters of the electric motor are selected to more specifically match the motor with a particular vehicle type, model, or manufacturer. -
Electric steering component 131 further comprises amotor control unit 313 is coupled withelectric motor 310 and with acontrol component 120 ofFIG. 2 viacoupling 115. InFIG. 3A ,electric motor 310 is coupled with thesteering column 340 via abracket 320. It is appreciated that in embodiments of the present invention,electric motor 310 may be coupled withsteering column 340 using another apparatus thanbracket 320. For example, in one embodiment,electric motor 310 may be coupled with a bracket which is attached via suction cups with the windshield or dashboard ofmobile machine 105. In another embodiment,electric motor 310 may be coupled with a pole which is extended between the floor and roof ofmobile machine 105. Furthermore, while the present embodiment showsmotor control unit 313 directly coupled withelectric motor 310, embodiments of the present invention are well suited to utilize other configurations. For example, in one embodimentmotor control unit 313 may be implemented as a sub-component ofcontrol unit 120 and may only send a control voltage toelectric motor 310 via an electrical coupling (not shown). In another embodiment,motor control unit 313 may be implemented as a separate unit which is communicatively coupled withcontrol unit 120 viacoupling 115 and withelectric motor 310 via an electrical coupling (not shown). - In embodiments of the present invention,
drive wheel 311 is coupled withsteering wheel 330 with sufficient friction such that rotation ofdrive 311 causes rotation ofsteering wheel 330. In embodiments of the present invention, a spring (not shown) maintains sufficient pressure forcoupling drive wheel 311 withsteering wheel 330. However, the spring does not maintain sufficient pressure betweendrive wheel 311 andsteering wheel 330 to pinch a user's fingers if, for example, the user is manually steeringmobile machine 105 and the user's fingers pass betweendrive wheel 311 andsteering wheel 330. While the embodiment ofFIGS. 3A and 3B showdrive wheel 311 contacting the outside portion ofsteering wheel 330, in other embodiments of the present invention,drive wheel 311 contact the inside portion ofsteering wheel 330. - In embodiments of the present invention,
electric motor 310 is reversable, thus, depending upon the steering command sent fromcontrol component 120,motor control unit 313 controls the current toelectric motor 310 such that it rotates in a clockwise or counter-clockwise direction. As a result,steering wheel 330 is turned in a clockwise or counter-clockwise direction as well. Typically, the current running throughelectric motor 310 is calibrated so thatdrive wheel 311 is turningsteering wheel 330 without generating excessive torque. This facilitates allowing a user to overrideelectric steering component 131. In embodiments of the present invention,electric motor 310 may be a permanent magnet brush direct current (DC) motor, a brushless DC motor, a stepper motor, or an alternating current (AC) motor. - In embodiments of the present invention,
motor control unit 313 can detect when a user is turningsteering wheel 330 in a direction counter to the directionelectric steering component 131 is turning. For example, a shaft encoder (not shown) may be used to determine whichdirection shaft 312 is turning. Thus, when a user turnssteering wheel 330 in a direction which counters the directionelectric motor 310 is turning, the shaft encoder detects that the user is turningsteering wheel 330 and generates a signal tomotor control unit 313. In response to determining that a user is turningsteering wheel 330,motor control unit 313 can disengage the power supplied toelectric motor 310. As a result,electric motor 310 is now freewheeling and can be more easily operated by the user. In another embodiment,motor control unit 313 whensteering wheel 330 is turned counter to the direction electric motor is turning, a circuit inmotor control unit 313 detects thatelectric motor 310 is stalling and disengages the power supplied toelectric motor 310. In another embodiment, a switch detects the rotation ofsteering wheel 330 and sends a signal tomotor control unit 313.Motor control unit 313 can then determine that the user is manually steeringmobile machine 105 and disengageelectric motor 310. As a result, when a user turnssteering wheel 330, their fingers will not be pinched if they pass betweendrive wheel 311 andsteering wheel 330 becauseelectric motor 310 is freewheeling when the power is disengaged. - Embodiments of the present invention are advantageous over conventional vehicle control systems in that they can be easily and quickly installed as an after market kit. For example, conventional control systems typically control a vehicle using solenoids and hydraulic flow valves which are coupled with the power steering mechanism of the vehicle. These systems are more difficult to install and more expensive than the above described system due to the higher cost of the solenoids and hydraulic flow valves as well as the additional labor involved in installing the system. The embodiment of
FIG. 3 can be easily bolted ontosteering column 340 and coupled withsteering controller 220. Additionally,electric motor 310 can be fitted to a variety of vehicles by simply exchangingbracket 320 for one configured for a particular vehicle model. Furthermore, embodiments of the present invention do not rely upon furrow feelers which typically must be raised from and lowered into a furrow when the end of the furrow is reached. As a result, less time is lost in raising or lowering the furrow feeler. -
FIGS. 4A and 4B show side and axial views respectively of asystem 400 for controlling a mobile machine in accordance with embodiments of the present invention. InFIG. 4A , the steering component (e.g.,electric steering component 131 ofFIG. 2 ) comprises anelectric motor 410 which is coupled withdrive wheel 411 viashaft 412 and amotor control unit 413.Motor control unit 413 coupleselectric motor 410 withsteering controller 220 ofFIG. 2 . InFIG. 4A ,electric motor 410 is connected withsteering column 440 viabracket 420. In the embodiment ofFIGS. 4A and 4B ,drive wheel 411 is coupled with asub wheel 431 which is coupled withsteering wheel 330 viabrackets 432. - In the embodiment of
FIGS. 4A and 4B ,electric motor 410 turns in a clockwise or counter-clockwise direction depending upon the steering command received bymotor control unit 413. As a result,drive wheel 411 causessub wheel 431 to turn in clockwise or counter clockwise direction as well. Utilizingsub wheel 431 prevents a user's fingers from being pinched betweensteering wheel 430 and drivewheel 411 if the user chooses to manually steer the vehicle. In embodiments of the present invention,sub wheel 431 can be easily and quickly coupled withsteering wheel 430 by, for example, attachingbrackets 432 to the spokes ofsteering wheel 430. -
FIGS. 5A and 5B are side and axial views respectively of asystem 500 for controlling a mobile machine in accordance with embodiments of the present invention. InFIG. 5A , the steering component (e.g.,electric steering component 131 ofFIG. 2 ) comprises anelectric motor 510 which is coupled withgear 511 viashaft 512 and with amotor control unit 513.Motor control unit 413 coupleselectric motor 510 withsteering controller 220 ofFIG. 2 . InFIG. 5A ,electric motor 510 is coupled withsteering column 540. -
FIG. 5B is a section view ofsystem 500 and shows steeringshaft 550 disposed withinsteering column 540. Agear 551couples steering shaft 550 withgear 511 ofelectric steering component 131. In the present embodiment,electric motor 510 turns in a clockwise or counter clockwise direction depending upon the steering command received bymotor control unit 513. As a result,gear 511 also turns in a clockwise or counter clockwise direction, thus causingsteering shaft 550 to turn due to the force conveyed bygear 551. While the present embodiment recites couplingelectric steering component 131 withsteering shaft 550 using gears, embodiments of the present invention are well suited for using other mechanical couplings such as a gear and chain, a belt and pulleys, etc. -
FIG. 6 is a flowchart of amethod 600 for implementing automatic vehicle control in accordance with embodiments of the present invention. In embodiments of the present invention,method 600 is implemented by, for example,control component 120 ofsystem 100 to facilitate implementing automatic vehicle control in a safe manner. It is noted that while the following discussions will cite usingmethod 600 in conjunction with agricultural vehicles, embodiments of the present invention may be used in other applications such as construction equipment and/or road servicing equipment such as snowplows or salt spreading trucks. - In
step 610 ofFIG. 6 , a course is determined for a vehicle along which the vehicle is to be automatically guided. In embodiments of the present invention, a user ofsystem 100 can enter coordinates which define a course forvehicle 105. In one embodiment, the user utilizeskeypad 140 to manually enter the coordinates which define the course for the vehicle. In embodiments of the present invention, the coordinates for more than one vehicle course may be entered by a user. For example, a user can programsystem 100 to follow a path (e.g., a road) comprising a series of curves which may be defined as a series of short straight segments. Thus, a series of vehicle courses may define a road whichvehicle 105 is guided along usingsystem 100. Additionally, in embodiments of the present invention, other information such as the width ofvehicle 105 or an implement coupled therewith (e.g., a plow attachment) may be entered intosystem 105. This facilitates determining a vector for steeringvehicle 105 to avoid overplanting or creating gaps in coverage. - In another embodiment, the coordinates may be stored in a memory device coupled with
system 100. For example, the coordinates of a previously stored vehicle course may be stored in a non-volatile memory or data storage device. Alternatively, the coordinates of the vehicle course may be determined by another computer system and transferred tosystem 100 using, for example, a portable memory storage device such as a SmartCard memory device, a universal serial bus (USB) memory device, or the like. In another embodiment, a wireless communication system may communicatively couplevehicle 105 with a communication network (e.g., the Internet) from which the vehicle course coordinates are accessed. In another embodiment, a user can drivevehicle 105 and setsystem 100 to continue the current direction for a designated distance. In another embodiment,vehicle 105 can be driven around the periphery of a field to define the outer edge of the work area. In so doing,position determining system 110 can determine the geographic position ofvehicle 105 and thus determine the edges of the field or work area. - In
step 620 ofFIG. 6 , an indication is received that a pre-defined parameter has been exceeded. Embodiments of the present invention utilize a variety of pre-defined parameters which are used to define operating parameters forsystem 100. For example, in embodiments of the present invention, when a system fault error is received (e.g., loss or degradation of a GPS signal, or other sensor), the generation of steering commands is suspended until the fault is corrected. - In embodiments of the present invention, other pre-defined parameters for
system 100 comprise, but are not limited to, a minimum vehicle speed, a maximum vehicle speed, an approach angle betweenvehicle 105 and the course vector, a cross-track error limit (e.g., the distance betweenvehicle 105 and the course vector), braking ofvehicle 105, a signal fromseat switch 180 or time outsensor 170, excessive tilt/roll ofvehicle 105, excessive roughness of terrain, excessive acceleration (including lateral acceleration) ofvehicle 105, and/or a manual override by a user (e.g., manually steering vehicle 105). - In
step 630 ofFIG. 6 , the generation of a steering command is suspended in response to receiving the indication ofstep 620. In embodiments of the present invention, if one of the pre-defined parameters discussed above with reference to step 620 is exceeded, steering commands for automatically guidingvehicle 105 are automatically suspended. In embodiments of the present invention, generating steering commands may not be resumed untilvehicle 105 is again operating within the pre-defined parameters and/or until a user ofvehicle 105 makes an indication that automatic vehicle control is to be resumed, thereby initiating a new vehicle guidance session. - Embodiments of the present invention facilitate safe operation of an automatic vehicle guidance system because the automatic vehicle guidance system is logically disengaged when pre-defined parameters are exceeded. In the prior art, mechanical sensors (e.g., furrow feelers) were used to determine whether a tractor was accurately tracking a plowed furrow and the only way to disengage the guidance system was to manually disengage the steering motor from the steering wheel of the vehicle or to manually disengage the furrow feelers from the furrow.
- Embodiments of the present invention, logically determine whether the vehicle is operating within a set of pre-defined parameters which may indicate that automatic vehicle control is desired by the user. For example, if
system 100 detects that the user is manually steeringvehicle 100, it is likely that the user does not wantsystem 100 to be generating steering commands. If these commands were implemented by a drive motor coupled with the steering wheel (e.g.,electric motor 310 ofFIG. 3 ), if may interfere with the user's control of the vehicle and lead to an unsafe operating condition. Additionally, if the vehicle is operated below a minimum vehicle speed, it may indicate that the user is attempting to stop the vehicle and thus may not want the automatic vehicle guidance system to take over operating the vehicle. Additionally, if the user is attempting, for example, a three-point turn, the stop/slow down action performed while transitioning to reverse causes system to be logically disengaged from controllingvehicle 105. The user can press an engage button to re-engage the current course vector if desired. - If the vehicle is operated above a maximum vehicle speed, it may indicate that the user has driven off of a field and therefore does not want the automatic vehicle guidance system to take over operating the vehicle. Additionally, if the vehicle has exceeded a distance parameter from a portion of the course vector, it may indicate, for example, that the user has driven
vehicle 105 off of a field and no longer desired automatic vehicle control to be implemented. Furthermore, if the user has drivenvehicle 105 off of a field, but is now driving parallel to the field (e.g., on a road parallel to the field), the maximum speed parameter disengages thesystem 100 to preventsystem 100 from attempting to control the vehicle while the user is operatingvehicle 105 on the road. - Thus, embodiments of the present invention facilitate a logical disengagement of
vehicle guidance system 100 while still allowing it to be physically coupled with the steering mechanism of the vehicle being controlled. This is much more convenient for users who previously had to manually disengage the drive motor from the steering wheel of the vehicle. For many users, this was especially tedious when performing repetitive operations, such as plowing a field, where manually disengaging the drive wheel was repeatedly performed. -
FIGS. 7A, 7B , 7C, 7D, and 7E are a flowchart of amethod 700 for implementing automatic vehicle control in accordance with embodiments of the present invention. It is noted that in addition to the steps shown inFIGS. 7A-7E , a user can suspend or terminate the operation ofsystem 100 at any time by, for example, pressing a designated button. Instep 701 ofFIG. 7A , power is supplied tosystem 100 by a user pressing the power button ofsystem 100. - In
step 702 ofFIG. 7A , a new guidance session is initiated. In embodiments of the present invention, the user indicates that a new guidance session is being initiated. In embodiments of the present invention, a sensor integrity check may be automatically performed when power is initiated to ensure that the sensors are providing valid information. For example, a GPS sensor (e.g., position determining system 110) can be operating properly (e.g., no system fault), but can be providing useless information when the system is under trees, or experiencing bad position quality. It is noted that integrity checks for sensors other than position determining system may be performed at this time. - In
step 703 ofFIG. 7A , course parameters for the new guidance session are received. As described above with reference to step 610 ofFIG. 6 ,system 100 accesses coordinates which define a vehicle course forvehicle 105. For example, a start point and end point of a swath, also known as the “A-B line,” are entered intosystem 100. - In
step 704 ofFIG. 7A , the control system is engaged. Once the user has entered the coordinates defining a vehicle course, the user manually indicates thatsystem 100 is to be engaged. This preventssystem 100 from automatically engaging as soon as the vehicle course coordinates are entered intosystem 100 and automatically guidingvehicle 105. - In
step 705 ofFIG. 7A , velocity data is received. In embodiments of the present invention, data is received from a variety of monitoring devices to determine the operating parameters ofvehicle 105. Instep 705, data indicating the current operating speed or velocity ofvehicle 105 is received bycontrol component 120. - In
step 706 ofFIG. 7A , a logical operation is performed to determine if the current velocity ofvehicle 105 is above a minimum velocity parameter. In embodiments of the present invention,control component 120 compares the current velocity ofvehicle 105 received instep 705 with a pre-defined minimum velocity parameter. Ifvehicle 105 is not exceeding the minimum velocity parameter (e.g., 5 miles per hour),method 700 continues atstep 725 and the generation of steering commands is suspended. Ifvehicle 105 is traveling above the minimum velocity parameter,method 700 proceeds to step 707. In one embodiment, the current velocity ofvehicle 105 must be above the minimum velocity parameter for five consecutive readings taken every 200 milliseconds (200 ms). - In
step 707 ofFIG. 7B , a logical operation is performed to determine if the current velocity ofvehicle 105 is below a maximum velocity parameter. In embodiments of the present invention,control component 120 compares the current velocity ofvehicle 105 received instep 705 with a pre-defined maximum velocity parameter. Ifvehicle 105 is exceeding the maximum velocity parameter (e.g., 15 miles per hour),method 700 continues atstep 725 and the generation of steering commands is suspended. Ifvehicle 105 is traveling below the maximum velocity parameter,method 700 proceeds to step 708. In one embodiment, the current velocity ofvehicle 105 must be below the maximum velocity parameter for five consecutive readings taken every 200 milliseconds (200 ms). - In
step 708 ofFIG. 7B , the current position data ofvehicle 105 is accessed. In embodiments of the present invention, the current position data ofvehicle 105 is obtained fromposition determining system 110. In embodiments of the present invention, a series of positions ofvehicle 105 may be accessed to determine the direction in whichvehicle 105 is traveling. - In
step 709 ofFIG. 7B , the course parameters received instep 703 are accessed. - In
step 710 ofFIG. 7B , a course vector is determined. In embodiments of the present invention, the course parameters received instep 703 define a first point, a second point, and a direction and distance between these two points. This information may be used in embodiments of the present invention to determine a vector of the course which is to be followed byvehicle 105. - In
step 711 ofFIG. 7B , the angle from the current position ofvehicle 105 to the course vector ofstep 710 is determined. In embodiments of the present invention, the current direction being traveled byvehicle 105, as determined instep 708 above, are compared with the direction of the course vector determined instep 710 above. - In
step 712 ofFIG. 7B , a logical operation is performed to determine whether the angle from the current position ofvehicle 105 to the course vector ofstep 710 is within a pre-defined parameter. In embodiments of the present invention, if the angle between these two directions exceeds a pre-defined entry angle parameter (e.g., 300 from the course vector direction),method 700 proceeds to step 725 and the generation of steering commands is suspended. If the angle between these two directions does not exceed the pre-defined entry angle parameter,method 700 proceeds to step 713. In one embodiment, the angle from the current position ofvehicle 105 to the course vector ofstep 710 must be within the pre-defined approach angle parameter for five consecutive readings taken every 200 milliseconds (200 ms). - In
step 713 ofFIG. 7C , the distance from the current position ofvehicle 105 to a point on the course vector is determined. In embodiments of the present invention,system 100 utilizes data fromposition determining system 110 to determine the current location ofvehicle 105. - In
step 714 ofFIG. 7C , a logical operation is performed to determine whether the distance from the current position ofvehicle 105 to a point on the course vector is within a pre-defined parameter. In embodiments of the present invention, the course vector is defined as a series of geographic positions. Thus,system 100 may be used to determine the distance ofvehicle 105 to a point comprising the course vector. - In one embodiment of the present invention, a user can enter additional information into
system 100 such as the width of an implement coupled withvehicle 105. For example, ifvehicle 105 is pulling a plow with a width of 30 feet, this information can be used to determine if the distance betweenvehicle 105 and a point of the course vector, also known as the “cross-track error,” exceeds a pre-defined parameter. For example, the pre-defined distance parameter may define the maximum distance betweenvehicle 105 and a point on the course vector as being no farther than 3 feet,” of the implement coupled withvehicle 105. Thus, if vehicle is more than 3 feet from a point of the designated course vector,method 700 proceeds to step 725 and the generation of steering commands is suspended. While the present embodiment recites a cross-track error of no more than 3 feet, this can be a greater or lesser number in embodiments of the present invention. - In embodiments of the present invention, if the distance between
vehicle 105 and a point of the course vector exceeds the pre-defined cross-track error parameter,method 700 proceeds to step 725 and the generation of steering commands is suspended. If the distance betweenvehicle 105 and a point of the course vector does not exceed the pre-defined cross-track error parameter,method 700 proceeds to step 715. In one embodiment, the distance from the current position ofvehicle 105 to a point on the course vector must be within the pre-defined cross-track error parameter for five consecutive readings taken every 200 milliseconds (200 ms). - In
step 715 ofFIG. 7C , the current flow data from a current sensor is accessed. In embodiments of the present invention,motor control unit 313 is operable for determining the amount of current flowing intoelectric motor 310 and/or determining whether a user is manually operatingsteering wheel 330 ofvehicle 105. In another embodiment, only current flow data is accessed bymotor control unit 313 and is sent viacoupling 115 to controlcomponent 120. - In
step 716 ofFIG. 7C , a logical operation is performed to determine if a manual disengagement ofsystem 100 disqualifies automatic re-engagement. For example, based upon the data accessed instep 715,system 100 can determine if a user is attempting to manually operatevehicle 105. If the disengagement ofsystem 100 is interpreted as an attempt by the operator ofvehicle 105 to avoid a possible safety risk, re-engagement of automatic vehicle control is prevented andmethod 700 proceeds to step 725 wherein the generation of steering commands is suspended. If it is determined that there was not a disqualifying disengagement,method 700 proceeds to step 717. - In
step 717 ofFIG. 7C , a logical operation is performed to determine whether a system fault error has been received. In embodiments of the present invention, device polling may be performed to determine if a system error condition exists with a component ofsystem 100. In other embodiments, each component may independently generate a message to controlcomponent 120 conveying that a system error has occurred. It is noted that reception of a system fault error message may be received at any time inmethod 700 and cause an immediate suspension of steering commands. In embodiments of the present invention, if a system fault error conditions exists,method 700 proceeds to step 725 and the generation of steering commands is suspended. If no system fault error condition exists,method 700 proceeds to step 718. - In
step 718 ofFIG. 7D , a logical operation is performed to determine whether the seat switch is engaged. As described above with reference toFIG. 1A , embodiments of the present invention may utilize a seat switch (e.g., 160) to determine whether an operator is seated invehicle 105. If it is determined that an operator is seated invehicle 105,method 700 proceeds to step 719. If it is determined that no operator is seated invehicle 105,method 700 proceeds to step 725. - In
step 719 ofFIG. 7D , a logical operation is performed to determine whether the time out period is within limits. As described above, in embodiments of thepresent invention system 100 may also comprise an optional time outsensor 170. Typically, an operator orvehicle 105 periodically actuates time outsensor 170 to confirm that the operator is still conscious and/or alert. If the operator does not actuate time outsensor 170 within a pre-determined time out parameter,method 700 proceeds to step 725. If the operator has actuated time outsensor 170 within the pre-determined time out parameter,method 700 proceeds to step 720. - In
step 720 ofFIG. 7D , a logical operation is performed to determine whethervehicle 105 is within an defined work area. Ifvehicle 105 is within an defined work area,method 700 proceeds to step 721. Ifvehicle 105 is outside of an defined work area,method 700 proceeds to step 725. Referring now toFIG. 11 ,vehicle 105 has been driven once around the periphery offield 1101. While driving around the periphery offield 1101,system 100 determines the geographic position of vehicle at various points around the periphery. In embodiments of the present invention,system 100 may define a border (e.g., 1105) relative to the location of the antenna ofsystem 100. In the example ofFIG. 11 , the border is defined at the inner edge of implement 801. However, it is noted that the border may be defined at a greater or lesser distance relative to the location ofantenna 107 in embodiments of the present invention. The area (e.g., 1150) betweenborder 1105 and the outer edge offield 1101 is referred to as the “headlands.” Typically, no planting or spraying is performed in the headlands area. The area withinborder 1105 is defined as the work area (e.g., 1160) forvehicle 105. - In operation, when the operator begins
swath 1110,vehicle 105 is driven topoint 1111. Becausevehicle 105 is outside of the work area when driving withinheadlands 1150,system 100 is automatically disengaged. Furthermore, while vehicle is outside ofwork area 1160,system 100 will not automatically re-engage. In other words, unless a manually activated engagement signal is received,system 100 does not generate steering commands. After completingswath 1110,vehicle 105 is outside ofwork area 1160 andsystem 100 is automatically disengaged. As a result,vehicle 105 has to be manually turned throughturn 1115. Upon reachingpoint 1121 ofswath 1120, the operator can manually re-engagesystem 100. In one embodiment, the operator also enters data which definespoint 1122 ofswath 1120 andsystem 100 determines a vector which comprisespoints point 1121, the swath calculation is performed bysystem 100. In other word,system 100 will guidevehicle 105 on a course that is essentially parallel withswath 1110 and displaced by a distance which approximates the width of implement 801. It is noted that whenvehicle 105 is driven to a different field or work area,system 100 disengages to permit the operator to manually steer the vehicle. It is noted that the method for establishing a work area discussed above is one of a variety of methods for doing so. In other embodiments, the work area may be defined by accessing previously stored data via, for example, a media storage device, or via a wireless data connection. - Referring again to
FIG. 7D , In step 721 a logical operation is performed to determine whether the brake ofvehicle 105 has been activated. As described above, embodiments of the present invention may optionally comprise a brake switch sensor (e.g., 180) which indicates whether an operator ofvehicle 105 has activated the braking system. If it is determined that the operator has actuated the braking system,method 700 proceeds to step 725. If it is determined that the operator has not yet actuated the braking system,method 700 proceeds to step 722. - In step 722 of
FIG. 7E , a logical operation is performed to determine whether the motion ofvehicle 105 is within roll, pitch, or yaw limits, or a combination thereof. This can be determined by accessing data fromTCM 150 which may utilize motion sensors to determine whether excessive motion ofvehicle 105 is exhibited in one or more of these planes of motion. Alternatively, this information can be determined by accessing position data fromposition determining system 110. If it is determined that excessive motion in one or more of these planes of motion is within pre-determined limits,method 700 proceeds to step 723. If it is determined that excessive motion in one or more of these planes of motion is not within pre-determined limits,method 700 proceeds to step 725. - In
step 723 ofFIG. 7E , a logical operation is performed to determine whether acceleration ofvehicle 105 is within pre-determined limits. Again,TCM 150 can be used to determine whethervehicle 105 has been accelerated beyond pre-determined limits. This may indicate whethervehicle 105 has struck an object, or run into a ditch, rolled over, etc. In embodiments of the present invention, if it is determined that acceleration ofvehicle 105 is within pre-determined limits,method 700 proceeds to step 724. If it is determined that acceleration ofvehicle 105 exceeds the pre-determined limits,method 700 proceeds to step 725. - In
step 724 ofFIG. 7E , a logical operation is performed to determine whether valid GPS information is being received. This step is similar to the sensor integrity check performed as described above with reference to step 702. It is noted that the sensor integrity check may be performed on a position determining system other than GPS in embodiments of the present invention. If the GPS system (e.g.,position determining system 110 ofFIG. 1 ) is receiving valid information,method 700 returns to step 705. If it is determined that the GPS system is not receiving valid information,method 700 proceeds to step 725. - In
step 725 ofFIG. 7C , the generation of a steering command is suspended. In embodiments of the present invention, steering commands from steering controller are suspended. In one embodiment, the steering commands are simply not conveyed tosteering component 130. In another embodiment, the steering commands are not generated at all. In another embodiment, course commands fromvehicle guidance system 210 may be interrupted to preventsteering controller 220 from generating the steering commands. -
FIG. 8 shows a vehicle implementing automatic vehicle control in accordance with embodiments of the present invention. InFIG. 8 , a user is operating a tractor (e.g., vehicle 105) pulling aplow 801 in afield 810. The user initiatesvehicle guidance system 100 and indicates that a new guidance session is being initiated. The user then enters the coordinates (e.g., first coordinate 821 and second coordinate 822) offirst swath 820. In embodiments of the present invention,system 100 determines the geographic position of first coordinate 821 and second coordinate 822, and a direction and distance of the vector between these two points. In so doing,system 100 has determined a course (e.g., first swath 820) forvehicle 105. Vehicle operation commences when the user engagessystem 100 by pressing an engage button. -
Vehicle 105 then proceeds downswath 820 based upon steering commands generated bycontrol component 120. In embodiments of the present invention, the user controls the speed ofvehicle 105 whileguidance system 100 automatically controls the steering ofvehicle 105 to guide it along the course defined byfirst swath 820. Thus, in embodiments of the present invention, as long as the user maintains the velocity ofvehicle 105 between the upper and lower speed limits, steering commands continue to be generated bysystem 100. - When
vehicle 105 reaches the end offirst swath 820, the user manually turns the steering wheel ofvehicle 105 to initiate a turn indicated byarrow 830.Vehicle guidance system 100 detects that the user is manually controlling vehicle 105 (e.g., step 716 ofFIG. 7 ) and automatically suspends generating steering commands. This preventssystem 100 from generating steering commands in an attempt to directvehicle 105 back ontofirst swath 820 and thus conflicting with the manual operation ofvehicle 105. In one embodiment,vehicle guidance system 210 continues to generate vehicle course commands to steeringcontroller 220, however, steeringcontroller 220 does not generate steering commands in response to those course commands. In another embodiment, vehicle course commands fromvehicle guidance system 210 are suspended as well. - As long as the user maintains the minimum speed throughout
turn 830, the user can enter the coordinates for a new swath (e.g., 840) by entering a first coordinate 841 and a second coordinate 842. At some point ofturn 830, the user can re-engagesystem 100 by pressing a button.System 100 will then determine the direction and distance of the course vector (e.g., 840) as well as the current geographic position and course ofvehicle 105. Because the width ofplow 801 is known tosystem 100, first coordinate 841 can be determined bysystem 100 to position the edge ofplow 801 so that gaps or overplowing is minimized. Ifvehicle 105 is within the pre-defined distance parameter and the entry angle betweenvehicle 105 andswath 840 is within parameters,system 100 will again initiate automatically controlling the steering ofvehicle 105 as it is guided along the course ofswath 840. Additionally,system 100 can indicate to the user that control of the steering can be relinquished by the user at some point onturn 830.System 100 will then control the steering ofvehicle 105 so that it is guided tofirst point 841 automatically and continue to steer the vehicle along that course. - At the end of
swath 840, the user again manually steersvehicle 105 through the turn defined byarrow 850. As described above, as long as the user maintains the speed ofvehicle 105 above the minimum speed parameter, the user can enter the coordinates of swath 860 (e.g., first coordinate 861 and second coordinate 862), press the engage button, andsystem 100 will generate steering commands to guidevehicle 105 alongswath 860. - At the end of
swath 860, the user finishes plowingfield 810 steersvehicle 105 toroad 870. As the user drivesvehicle 105 in the direction shown byarrow 880,system 100 determines thatvehicle 105 has exceeded the distance parameter. For example, the distance betweenvehicle 105 andswath 860 now exceeds the maximum cross-track error distance of 3 swaths based upon the width ofplow 801. - With reference to
FIG. 9 , portions of the present invention are comprised of computer-readable and computer-executable instructions that reside, for example, invehicle guidance system 210. It is appreciated thatvehicle guidance system 210 ofFIG. 9 is exemplary only and that the present invention can be implemented by other computer systems as well. - In the present embodiment,
vehicle guidance system 210 includes an address/data bus 901 for conveying digital information between the various components, a central processor unit (CPU) 902 for processing the digital information and instructions, a volatilemain memory 903 comprised of volatile random access memory (RAM) for storing the digital information and instructions, and a non-volatile read only memory (ROM) 904 for storing information and instructions of a more permanent nature. In addition,vehicle guidance system 210 may also include a data storage device 905 (e.g., a magnetic, optical, floppy, or tape drive or the like) for storing vast amounts of data. It should be noted that the software program of the present invention for implementing automatic vehicle control can be stored either involatile memory 903,data storage device 905, or in an external storage device (not shown).Vehicle guidance system 210 further comprises afirst communication interface 906 coupled withbus 901 for receiving geographic position data fromposition determining system 110.Vehicle guidance system 210 also comprises asecond communication interface 907 coupled withbus 901 for conveying course correction commands to steeringcontroller 220. In embodiments of the present invention,first communication interface 906 andsecond communication interface 907 are serial communication interfaces. -
FIG. 10 is a flowchart of amethod 1000 for preventing automatic re-engagement of automatic vehicle control in accordance with embodiments of the present invention. It is noted thatmethod 1000 may be implemented bysystem 100 described above with reference toFIG. 1A . Instep 1010, a course for guiding a vehicle between a first geographic position and a second geographic position using an automatic vehicle control system is determined. As described above with reference to step 610 ofFIG. 6 ,system 100 can receive manually input coordinates from a user, a media storage device (e.g., a memory device), via a wireless data communication link, derived from current course data, or a combination thereof. - In
step 1020 ofFIG. 10 , an indication is received that a pre-defined parameter of the automatic vehicle control system has been exceeded. As described above with reference to step 620 ofFIG. 6 , there are a variety of parameters which are monitored bysystem 100 which indicate when it may be advantageous to logically disengagesystem 100. For example, when a user is manually drivingvehicle 105 it may create an unsafe driving condition ifsystem 100 determines that the parameters for generating steering commands are still met. In such a situation,system 100 may attempt to guidevehicle 105 toward an obstacle or object which the operator ofvehicle 105 is actively trying to avoid. As another example, if the operator has finished working in a particular field and is moving to another field,system 100 may attempt to steervehicle 105 back to the field thatvehicle 105 has just left. Again, this may cause an unsafe situation for the operator and others in the vicinity. Thus, it may be desirable to establish parameters for disengagingsystem 100 automatically. - In
step 1030 ofFIG. 10 , the generation of steering commands via the automatic vehicle control system is suspended in response to receiving the indication as described above with reference to step 1020. As described above with reference to step 630 ofFIG. 6 , if one of the pre-defined parameters is exceeded, the generation of steering commands forvehicle 105 is suspended. This preventssystem 100 from controlling the direction ofvehicle 105. As stated above, this can be dangerous when the operator ofvehicle 105 is attempting to manually control the vehicle. As another example, ifvehicle 105 has run into a ditch, or is about to, continued control of the vehicle bysystem 100 may further exacerbate an already dangerous situation. - In
step 1040 ofFIG. 10 , the automatic re-engagement of the automatic vehicle control system is prevented until an engagement signal is received. In embodiments of the present invention, until an engagement signal is received bycontrol component 120, the generation of steering commands continues to be suspended. In embodiments of the present invention, course corrections may continue to be calculated byvehicle guidance system 210. However, they may not be sent tosteering controller 220 in order to generate a steering command. In embodiments of the present invention, the engagement signal is manually input by the operator ofvehicle 105. As a result, embodiments of the present invention prevent unintentional engagement of the automatic vehicle control system. As described above, this is advantageous in situations in which the operator has initiated manual control of the vehicle such as to avoid an obstacle or to drive between separate work areas. - The preferred embodiment of the present invention, a method and system for preventing automatic re-engagement of automatic vehicle control, is thus described. While the present invention has been described in particular embodiments, it should be appreciated that the present invention should not be construed as limited by such embodiments, but rather construed according to the following claims.
Claims (20)
1. A method for preventing automatic re-engagement of automatic vehicle control, said method comprising:
determining a course for a vehicle wherein said vehicle is to be automatically guided along said course between a first geographic position and a second geographic position using an automatic vehicle control system;
receiving an indication that a pre-defined parameter of said automatic vehicle control system has been exceeded;
suspending the generation of steering commands via said automatic vehicle control system in response to said receiving of said indication; and
preventing said automatic re-engagement of said automatic vehicle control system wherein the suspension of the generation of steering commands is continued until an engagement signal is received.
2. The method as recited in claim 1 wherein said engagement signal indicates that said vehicle is being controlled by an operator.
3. The method as recited in claim 2 wherein said engagement signal indicates that said operator is seated in said vehicle.
4. The method as recited in claim 1 wherein said engagement signal indicates that said vehicle is within a defined work area.
5. The method as recited in claim 1 wherein said engagement signal indicates excessive vehicle movement with respect to at least one axis selected from the group consisting essentially of a roll axis, a pitch axis, and a yaw axis.
6. The method as recited in claim 1 further comprising:
receiving an indication of excessive vehicle acceleration from said automatic vehicle control system.
7. The method as recited in claim 6 wherein receiving said indication of excessive vehicle acceleration comprises receiving said indication from a position determining system coupled with said automatic vehicle control system.
8. A computer usable medium having computer readable program code embodied therein for causing a computer system to perform a method for preventing automatic re-engagement of automatic vehicle control, said method comprising:
determining a course for a vehicle wherein said vehicle is to be automatically guided along said course between a first geographic position and a second geographic position using an automatic vehicle control system;
receiving an indication that a pre-defined parameter of said automatic vehicle control system has been exceeded;
suspending the generation of steering commands via said automatic vehicle control system in response to said receiving of said indication; and
preventing said automatic re-engagement of said automatic vehicle control system wherein the suspension of the generation of steering commands is continued until an engagement signal is received.
9. The computer usable medium of claim 8 wherein said engagement signal indicates that said vehicle is being controlled by an operator.
10. The computer usable medium of claim 9 wherein said engagement signal indicates that said operator is seated in said vehicle.
11. The computer usable medium of claim 8 wherein said engagement signal indicates that said vehicle is within a defined work area.
12. The computer usable medium of claim 8 wherein said engagement signal indicates excessive vehicle movement with respect to at least one axis selected from the group consisting essentially of a roll axis, a pitch axis, and a yaw axis.
13. The computer usable medium of claim 8 further comprising:
receiving an indication of excessive vehicle acceleration from said automatic vehicle control system.
14. The computer usable medium of claim 13 wherein receiving said indication of excessive vehicle acceleration comprises receiving said indication from a position determining system coupled with said automatic vehicle control system.
15. A system for implementing automatic vehicle control, said system comprising:
a position determining component for determining the geographic position of said vehicle;
a steering component for controlling the steering mechanism of said vehicle; and
a control component coupled with said position determining component and with said steering component, said control component for generating a course correction in response to receiving position data from said position determining component, said control component further for suspending the generation of said course correction in response to said receiving an indication that a pre-defined parameter has been exceeded until an engagement signal is received.
16. The system of claim 15 further comprising:
a seat switch for indicating that an operator is seated in said vehicle.
17. The system of claim 15 further comprising:
a time out sensor for indicating that said vehicle is being controlled by an operator.
18. The system of claim 15 further comprising:
a brake sensor switch for indicating when the braking mechanism of said vehicle is engaged.
19. The system of claim 15 further comprising:
a component for indicating when said vehicle has exceeded a parameter with respect to at least one axis selected from the group consisting essentially of a roll axis, a pitch axis, and a yaw axis.
20. The system of claim 15 further comprising:
a component for indicating when said vehicle has exceeded an acceleration parameter.
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Also Published As
Publication number | Publication date |
---|---|
CN101069140A (en) | 2007-11-07 |
EP1817647B1 (en) | 2014-08-20 |
WO2006060040A1 (en) | 2006-06-08 |
US20060116798A1 (en) | 2006-06-01 |
CN100555139C (en) | 2009-10-28 |
EP1817647A1 (en) | 2007-08-15 |
US7574290B2 (en) | 2009-08-11 |
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