A control system for an earth moving machine having an earth moving tool is provided. A position detection system is configured to provide an indication of a geographical position of the earth moving machine. A tool position sensor is configured to provide an indication of a position of the earth moving tool relative to the earth moving machine. The tool force sensor is configured to provide an indication of force exerted on the earth moving tool. A controller is configured to determine a tool engagement with a work surface at a position indicated by the position detection system based on the indication of the tool position. The controller is further configured to generate jobsite density information based on the tool engagement and the indication of force exerted on the earth moving tool, the controller being further configured to cause a wireless communication module to provide an indication of the jobsite density for the position indicated by the position detection system to at least one remote device.

In a blade control device, a blade operation control part outputs a command for raising and lowering a blade such that a position deviation between a blade position calculated by a blade position calculating part and a blade target position approaches zero in a case where a blade load is equal to or less than a second load threshold value, and outputs a command for raising the blade in a case where the blade load is greater than the second load threshold value. In a case where an update condition is satisfied, the update condition being set in advance so as to associate the blade load and a first load threshold value with each other, a target position setting part updates the blade target position using the blade position obtained when the update condition is satisfied as a reference.

A blade operation control part of a blade control device controls operation of a blade such that when a blade load is equal to or less than a first load threshold value and a position deviation is equal to or greater than a position threshold value, the blade is lowered to make the position deviation approach zero. The blade operation control part controls operation of the blade such that the blade is raised regardless of the position deviation when the blade load is equal to or greater than a second load threshold value.

A work vehicle control system includes an actual topography acquisition device and a controller. The actual topography acquisition device acquires actual topography information, which indicates an actual topography of a work target. The controller acquires the actual topography information from the actual topography acquisition device. The controller generates a command signal to move the work implement along a locus positioned above the target topography by a predetermined distance when the actual topography is positioned below the target topography of the work target.

In a blade control device, in a case where an update condition set in advance is satisfied, a virtual design surface setting part sets a virtual design surface, using a blade position when the update condition is satisfied as a reference, at an angle equivalent to a vehicle body angle, and a blade operation control part restricts raising and lowering operation of a blade such that the blade conducts the raising and lowering operation above the virtual design surface.

A guide system for planning missions of autonomous or semi-autonomous material displacement machines includes an operator interface and at least one computer coupled with the operator interface. The at least one computer is structured to receive working elevation information associated with missions executed by machines and indicative of working elevation parameters dependent upon disposition of a material displaced by the machines. The guide system is further structured to receive surrounding terrain information and compare the working elevation parameters to a surrounding elevation parameter. The guide system produces elevation variance alerts based on the comparison, and displays the elevation variance alerts in an operator-perceptible form such as graphically on a display in an operator interface.

A transmission system for a machine is coupled to an engine of the machine that is adapted to generate power. The transmission system includes a hydraulic power path including a variator coupled to the engine. The transmission system also includes a mechanical power path. The mechanical power path includes a first gear arrangement including a plurality of gears. The mechanical power path also includes a second gear arrangement including a plurality of gears. The second gear arrangement is coupled with the first gear arrangement to receive the variable rotational power from the first gear arrangement. The mechanical power path further includes a first clutch assembly and a second clutch assembly. Further, the second gear arrangement directs the variable rotational power received from the first gear arrangement towards a final output member of the machine in a selected direction.

A work machine includes: a first posture detection device which detects a posture of an upper slewing body with respect to a lower travelling body; a second posture detection device which detects a posture of a blade; a laser beam receiver which is provided to the upper slewing body and can receive a laser beam emitted from a laser beam emitter; and a calculation unit which calculates a height position of a cutting edge of the blade with respect to a surface to be constructed. The calculation unit calculates the height position of the cutting edge of the blade with respect to the surface to be constructed based on a laser beam receiving position where the laser beam is received by the laser beam receiver, a posture of the upper slewing body with respect to the lower travelling body, and a posture of the blade.

A system for controlling a ground engaging work implement includes a machine position sensor, a work surface position sensor, a work implement position sensor, and a controller. The controller determines the position of the machine, determines the topography of the work surface, determines a location of a pre-task trigger location adjacent the task start location, and determine a position of the lowest surface of the ground engaging work implement. The controller generates traverse signals to propel the machine from the task end location towards the task start location, generate work implement height signals to maintain the lowest surface of the ground engaging work implement at or above the traversing threshold height as the machine travels from the task end location towards the task start location, and generate work implement lowering signals to lower the work implement to the pre-task threshold height after the machine passes the pre-task trigger location.

A control system for a work vehicle includes a storage device and a controller in communication with the storage device. The storage device stores target parameter data defining a relationship between a movement distance of the work vehicle and a target parameter related to a target digging amount of a work implement of the work vehicle. The target parameter data includes digging time data defining a relationship between the movement distance of the work vehicle within a predetermined digging area and the target parameter. The controller determines a target return distance from a distance of the digging area defined in the target parameter data, and determines a position returned from a predetermined reference position by the target return distance as a recommended digging start position.