Abstract: A method of controlling a work tool with respect to a design surface gradient identifies surface gradient and determines a desired angle for the work tool. Movement of the machine is monitored and the distance between the design surface gradient and the work tool is determined. The angle of the work tool is varied based on one or more of these parameters.

Abstract: A method of controlling a machine during an excavating operation is provided. Stabilizers are deployed to ground contact to stabilize the machine at a first set-up position. Excavating is performed with an excavating assemblage during a first excavating phase while the machine is stabilized at the first set-up position. An automated machine preparation for repositioning mode is initiated for preparing the machine, after the excavating phase, for repositioning to a second set-up position for a second excavating phase, by activating an input device to send input signals to a controller. Output signals are delivered from the controller to control automated machine preparation for repositioning to the second set-up position.

Abstract: A method of repositioning a machine during an excavating operation from a first machine position to a second machine position is provided. A target distance to the second machine position is selected. An operator input device configured to send a control input signal to a control module to initiate a repositioning phase is activated. During a repositioning phase, the machine is moved toward the second position while an operator maintains control of movement. A determination is made when the machine has traveled the target distance. The machine is stopped under automated machine control at the second machine position.

Abstract: A system and method of assisting an operator of an excavating machine includes recommending a hop distance to move the machine based on the maximum distance that the machine can move and still be able to reach the bottom of the excavation that has already been dug by the machine during an excavating operation.

Abstract: A method is provided for enhancing the repositioning of an excavating machine, including an excavating assemblage, from one set-up position to a next, subsequent set-up position. A joystick is controlled in implement control mode to operate at least one of a boom, a stick, and a bucket of the excavating assemblage during a first excavating phase from a first machine set-up position. The first excavating phase is terminated and, during a machine repositioning phase, the machine is moved to a second machine set-up position for a second excavating phase at the second machine set-up position. After terminating the first excavating phase and before moving the machine to the second machine set-up position, an input/display device is accessed and activated to convert the joystick from implement control mode to machine control mode. At least machine steering and machine propulsion are controlled with the joystick set in the machine control mode during the machine repositioning phase.

Abstract: A system is provided for controlling off-fall during trench excavation. The system includes a trench excavating assemblage. A mechanism moves the trench excavating assemblage from a position within a trench to be excavated to a position for dumping excavated material. A control system is configured to operate the trench excavating assemblage in an automated off-fall control mode to remove and/or compact off-fall along at least one edge of the trench.

Abstract: A method of controlling a work tool with respect to a design surface gradient identifies surface gradient and determines a desired angle for the work tool. Movement of the machine is monitored and the distance between the design surface gradient and the work tool is determined. The angle of the work tool is varied based on one or more of these parameters.

Abstract: A control system for a machine operating at a excavation site is disclosed. The control system may have a positioning device configured to determine a position of the machine, and a controller in communication with the positioning device. The controller may be configured to receive information regarding a predetermined task for the machine, receive the machine's position, and receive a location of an obstacle at the excavation site. The control system may also be configured to recommend placement of the machine to accomplish the predetermined task based on the received machine position and obstacle location.

Abstract: A method of repositioning a machine during an excavating operation from a first machine position to a second machine position is provided. A target distance to the second machine position is selected. An operator input device configured to send a control input signal to a control module to initiate a repositioning phase is activated. During a repositioning phase, the machine is moved toward the second position while an operator maintains control of movement. A determination is made when the machine has traveled the target distance. The machine is stopped under automated machine control at the second machine position.

Abstract: A method of assisting an operator of an excavating machine is disclosed. The method includes recommending a hop distance to move the machine based upon the maximum distance the machine can move and still be able to reach the bottom of the excavation that has already been dug by the machine during an excavating operation.

Abstract: A method is provided for enhancing the repositioning of an excavating machine, including an excavating assemblage, from one set-up position to a next, subsequent set-up position. A joystick is controlled in implement control mode to operate at least one of a boom, a stick, and a bucket of the excavating assemblage during a first excavating phase from a first machine set-up position. The first excavating phase is terminated and, during a machine repositioning phase, the machine is moved to a second machine set-up position for a second excavating phase at the second machine set-up position. After terminating the first excavating phase and before moving the: machine to the second machine set-up position, an input/display device is accessed and activated to convert the joystick from implement control mode to machine control mode. At least machine steering and machine propulsion are controlled with the joystick set in the machine control mode during the machine repositioning phase.

Abstract: A method of controlling a machine during an excavating operation is provided. Stabilizers are deployed to ground contact to stabilize the machine at a first set-up position. Excavating is performed with an excavating assemblage during a first excavating phase while the machine is stabilized at the first set-up position. An automated machine preparation for repositioning mode is initiated for preparing the machine, after the excavating phase, for repositioning to a second set-up position for a second excavating phase, by activating an input device to send input signals to a controller. Output signals are delivered from the controller to control automated machine preparation for repositioning to the second set-up position.

Abstract: A control system for a machine operating at a excavation site is disclosed. The control system may have a positioning device configured to determine a position of the machine, and a controller in communication with the positioning device. The controller may be configured to receive information regarding a predetermined task for the machine, receive the machine's position, and receive a location of an obstacle at the excavation site. The control system may also be configured to recommend placement of the machine to accomplish the predetermined task based on the received machine position and obstacle location.

Abstract: A system is provided for controlling off-fall during trench excavation. The system includes a trench excavating assemblage. A mechanism moves the trench excavating assemblage from a position within a trench to be excavated to a position for dumping excavated material. A control system is configured to operate the trench excavating assemblage in an automated off-fall control mode to remove and/or compact off-fall along at least one edge of the trench.

Abstract: In order for work, such as excavation, to occur at a job site, a job site plan with various job site features must be accurately translated to ground locations at the job site. The present disclosure locates a job site feature at a job site by storing a job site plan including at least one job site location on a computer readable data storage medium of an apparatus. An apparatus location is determined via at least one location sensor and compared to the at least one job site location. A job site locating algorithm also stored on the computer readable data storage medium is operable to indicate when the at least one job site location and the apparatus location are coincident.

Abstract: A method for controlling movement of a work tool includes the step of identifying a predefined digging boundary and determining the current position of the work tool. A control signal is generated to change the position of the work tool. A requested motion vector is determined for the work tool based on the control signal. A determined force is generated to apply to the work tool. It is based on the requested motion vector and has a normal component that is scaled to prevent the work tool from crossing the predefined digging boundary. One aspect is directed to a control system for a work tool on a work implement assembly.

Abstract: A method of controlling the movement of a work machine arm having a series of hydraulic cylinders operatively engaged with the work machine arm includes receiving a signal from an input device to change the position of the work machine arm and determining an extension amount of one or more of the series of hydraulic cylinders. The extension amount of one or more of the series of hydraulic cylinders is changed to effect the change in the position of the work machine arm. The changes in the extension amount of the one or more of the series of hydraulic cylinders are ordered based on a pre-selected priority of movement.

Abstract: A system and method for estimating the position of a mechanical linkage is disclosed. An estimated position of a mechanical linkage is set to an initial position. The movement of the mechanical linkage is controlled based on a signal from an input device. The estimated position of the mechanical linkage is updated based upon the movement of the mechanical linkage. A determination is made when the estimated position of the mechanical linkage substantially corresponds to an actual position of the mechanical linkage.

Abstract: A system and method for estimating the position of a mechanical linkage is disclosed. An estimated position of a mechanical linkage is set to an initial position. The movement of the mechanical linkage is controlled based on a signal from an input device. The estimated position of the mechanical linkage is updated based upon the movement of the mechanical linkage. A determination is made when the estimated position of the mechanical linkage substantially corresponds to an actual position of the mechanical linkage.

Abstract: A control system for orienting a swing axis of a work machine is disclosed. The work machine includes a swing frame and a frame structure, and the control system includes an operator interface configured to receive operator inputs, wherein the operator inputs represent a desired orientation of the swing axis of the swing frame. The control system also includes a sensor assembly configured to determine an actual orientation of the swing axis of the swing frame and a controller configured to compare the desired orientation to the actual orientation of the swing axis to determine a swing angle. The controller is adapted to output the swing angle. The swing axis may be adjusted by adjusting the work machine frame or by adjusting a frame assembly independent of the work machine frame.